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100 Interesting Physics Topics For Research Paper In 2023

Searching for a topic in physics can be one of the more difficult challenges for students at any level. Teachers and professors want their students to research and write something original. They also want students to challenge themselves by pushing the envelope and studying new areas in the field. This can be overwhelming for students and trying to come up with even a handful of physics topics might seem an impossible task.

Choosing Physics Topics For a Project

A good physics research topic should be broad enough to let you find plenty of material to answer all of the important questions. It should, however, also be narrow enough to fit within the parameters of your assignment. We can help you with that. Check out our list of physics topics that cover a wide range of areas within the field:

Physics Research Paper Topics for High School

How much are solar panels affected by dust?
What is the discharge amount from a pinhole on a water bottle?
Is time travel adequately explained in literature?
Why do some carpets have more static buildup?
How is light impacted when cast through a sugar solution?

Five Cool Physics Topics to Do Quickly

How strong is human hair of different thicknesses?
Can eggs withstand more force from certain directions or angles?
Can a metal pendulum accurately predict the sex of a chicken?
What factors impact the heat capacity of different saltwater concentrations?
How are projectile miniature rockets affected by temperature?

Physics Research Topics for College

What are the mechanics of a perpetual clock?
How does circular motion impact the rotation of various spheres?
What are the components and nature of various atoms?
How does weather affect gravity in falling objects?
What role does physics play in the health care industry?

Physics Topics for Paper Graduate School

What are the primary characteristics of the laws of motion?
What are the major principles of Lorentz force law in relation to electromagnetism?
How will quantum computing impact the physics of the 2020s?
Will gravitational waves prove that Einstein’s theories are incorrect?
How does rotational motion work when using different types of torque?

Special Topics in Calamity Physics

How are calamity physics different from chaos theory?
Do the concepts in Calamity Physics reflect reality?
How do physic professionals view the opinions in Calamity Physics?
Can Calamity Physics become a legitimate area of study?
Where did the author of Calamity Physics get her ideas from?

Physics IA Topics Ideas for Studying

What effect does temperature have on the speed of sound in a solid?
What impact does sugar have on water’s refractive index?
How does temperature influence the flight pattern of an item when fired?
In what ways does shade affect a solar panel’s power output?
How does the shape of a football affect its flight pattern?

Interesting Physics Topics for All

Are floating cities a reality in light of rising water levels?
Why was the 2020 Christmas Star such a rare phenomenon?
What impact will the development of superconductors have on physics?
How will the study of exotic materials be affected by superconductors?
Will new discoveries in physics lead to new green technologies?

AP Physics Topics for High School

How does one measure motion utilizing position-time charts?
How is a ball’s motion on its way down a mirror image of its upward motion?
How does one measure motion utilizing velocity-time charts?
What are the major principles of electrostatics?
Howe do simple pendulums and mass-spring systems work?

SAT Physics Topics Ideas for Studying

How do airplanes gather wing lift?
How does one measure the molecular sizes of various gases?
How do gravity and wind resistance affect the arc of a ball thrown in the air?
What patterns can be observed in an experiment involving paper airplane flights?
In what ways is an object in free fall affected by gravity acceleration?

Physics GRE Topics for Studying

How do magnetic fields in free space react to outside forces?
What are the major components of optics and wave phenomena?
How is a balloon’s surface area affective by weather?
How does sound travel in different environments?
What is the audible range of a human being?

MCAT Physics Topics Ideas for Studying

Understand the characteristics of average speed and velocity.
Understand how dimensions (distance and time) work in the Universe.
Explain what Newton’s first, second, and third laws state.
What is the law of Gravitation and what does it mean for the Earth’s physics?
How do weight and mass differ in the construction of buildings?

Five Fun Physics Topics to Do Quickly

How does kinetic energy help athletes improve performance?
How does caloric intake affect the energy humans generate?
What is the most effective way of optimizing a bottle rocket?
What is the difference between potential energy and kinetic energy?
How does the length and tension of a guitar string effect sound output?

Theoretical Physics Topics for Undergraduates

How can our understanding of physics help reduce global warming?
Why is physics essential to our society and how has it evolved?
What are the major principles of quantum mechanics?
What is the relationship between energy consumption and nuclear physics?
What are the major factors that affect the trajectory of a rocket going to space? Discover more space topics .

Interesting Modern Physics Topics

Why has the concept of cold fusion been contended by researchers?
Is cold fusion a legitimate physical science or is it speculative?
How can physics play a role in minimizing the effects of global warming?
Why have Nobel Prize-winning physicists been contradicted in recent years?
How is nanotechnology related to modern physics?

Great Physics Topics for Presentation

What are the major principles that make an atomic bomb acts?
How have the ideas for space and time explorations changed in the last 50 years?
What impact did Galileo have on the world view of physics?
What role did atomic particles play in building our universe?
Is the Hadron collider capable of starting a black hole?

Physics Regents Topics for Preparation

How much energy is expended when you go from walking to running?
What makes perpetual motion machines work?
What are the factors that affect drag in canoes?
What are the differences between conservative forces and potential energy?
In what ways is the conservation of energy affected by temperature?

Great Physics Paper Topics for a Short Project

What are the best ways to make a catapult with Popsicle sticks?
How to make a rudimentary prism at home?
What factors affect the rotational speed of a DC motor?
What characteristics lay within the concept of pyramid power?
How do sailboats convert wind power to move forward?

Good Physics Projects Topics for a Long Project

How much energy do solar panels input and output?
How much energy do solar panels lose over a day?
How did Stephen Hawking impact contemporary physics?
What is the difference between centripetal and centrifugal forces?
What are the measurement problems within quantum probability?

Physics Essay Topics Related to Everyday Situations

How does temperature affect different musical instruments?
How do you build a lawn sprinkler using a milk carton?
How do you minimize the risk of egg breakage in cartons?
Can light affect the shape and size of Jell-O?
What does Einstein’s theory of relativity state about our surroundings?

Physics is really hard. We understand this and have committed ourselves to assist students at all levels and dealing with all situations. Our experts have put together these physics topics to help students save some time. We can also help develop custom physics science topics to fit any assignment requirements.

Just give us a call, email us, or send us a message by chat. Our customer service team representatives are available to help with any physics project topics you need. An excellent custom thesis is not a problem for us. We’ll connect you with the most qualified experts and will lighten the burden of the most difficult assignments.

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25 Research Ideas in Physics for High School Students

Research can be a valued supplement in your college application. However, many high schoolers are yet to explore research , which is a delicate process that may include choosing a topic, reviewing literature, conducting experiments, and writing a paper.

If you are interested in physics, exploring the physics realm through research is a great way to not only navigate your passion but learn about what research entails. Physics even branches out into other fields such as biology, chemistry, and math, so interest in physics is not a requirement to doing research in physics. Having research experience on your resume can be a great way to boost your college application and show independence, passion, ambition, and intellectual curiosity !

We will cover what exactly a good research topic entails and then provide you with 25 possible physics research topics that may interest or inspire you.

What is a good research topic?

Of course, you want to choose a topic that you are interested in. But beyond that, you should choose a topic that is relevant today ; for example, research questions that have already been answered after extensive research does not address a current knowledge gap . Make sure to also be cautious that your topic is not too broad that you are trying to cover too much ground and end up losing the details, but not too specific that you are unable to gather enough information.

Remember that topics can span across fields. You do not need to restrict yourself to a physics topic; you can conduct interdisciplinary research combining physics with other fields you may be interested in.

Research Ideas in Physics

We have compiled a list of 25 possible physics research topics suggested by Lumiere PhD mentors. These topics are separated into 8 broader categories.

Topic #1 : Using computational technologies and analyses

If you are interested in coding or technology in general , physics is also one place to look to explore these fields. You can explore anything from new technologies to datasets (even with coding) through a physics lens. Some computational or technological physics topics you can research are:

1.Development of computer programs to find and track positions of fast-moving nanoparticles and nanomachines

2. Features and limitations to augmented and virtual reality technologies, current industry standards of performance, and solutions that have been proposed to address challenges

3. Use of MATLAB or Python to work with existing code bases to design structures that trap light for interaction with qubits

4. Computational analysis of ATLAS open data using Python or C++

Suggested by Lumiere PhD mentors at University of Cambridge, University of Rochester, and Harvard University.

Topic #2 : Exploration of astrophysical and cosmological phenomena

Interested in space? Then astrophysics and cosmology may be just for you. There are lots of unanswered questions about astrophysical and cosmological phenomena that you can begin to answer. Here are some possible physics topics in these particular subfields that you can look into:

5. Cosmological mysteries (like dark energy, inflation, dark matter) and their hypothesized explanations

6. Possible future locations of detectors for cosmology and astrophysics research

7. Physical processes that shape galaxies through cosmic time in the context of extragalactic astronomy and the current issues and frontiers in galaxy evolution

8. Interaction of beyond-standard-model particles with astrophysical structures (such as black holes and Bose stars)

Suggested by Lumiere PhD mentors at Princeton University, Harvard University, Yale University, and University of California, Irvine.

Topic #3 : Mathematical analyses of physical phenomena

Math is deeply embedded in physics. Even if you may not be interested solely in physics, there are lots of mathematical applications and questions that you may be curious about. Using basic physics laws, you can learn how to derive your own mathematical equations and solve them in hopes that they address a current knowledge gap in physics. Some examples of topics include:

9. Analytical approximation and numerical solving of equations that determine the evolution of different particles after the Big Bang

10. Mathematical derivation of the dynamics of particles from fundamental laws (such as special relativity, general relativity, quantum mechanics)

11. The basics of Riemannian geometry and how simple geometrical arguments can be used to construct the ingredients of Einstein’s equations of general relativity that relate the curvature of space-time with energy-mass

Suggested by Lumiere PhD mentors at Harvard University, University of Southampton, and Pennsylvania State University.

Topic #4 : Nuclear applications in physics

Nuclear science and its possible benefits and implications are important topics to explore and understand in today’s society, which often uses nuclear energy. One possible nuclear physics topic to look into is:

12. Radiation or radiation measurement in applications of nuclear physics (such as reactors, nuclear batteries, sensors/detectors)

Suggested by a Lumiere PhD mentor at University of Chicago.

Topic #5 : Analyzing biophysical data

Biology and even medicine are applicable fields in physics. Using physics to figure out how to improve biology research or understand biological systems is common. Some biophysics topics to research may include the following:

13. Simulation of biological systems using data science techniques to analyze biological data sets

14. Design and construction of DNA nanomachines that operate in liquid environments

15. Representation and decomposition of MEG/EEG brain signals using fundamental electricity and magnetism concepts

16. Use of novel methods to make better images in the context of biology and obtain high resolution images of biological samples

Suggested by Lumiere PhD mentors at University of Oxford, University of Cambridge, University of Washington, and University of Rochester

Topic #6 : Identifying electrical and mechanical properties

Even engineering has great applications in the field of physics. There are different phenomena in physics from cells to Boson particles with interesting electrical and/or mechanical properties. If you are interested in electrical or mechanical engineering or even just the basics , these are some related physics topics:

17. Simulations of how cells react to electrical and mechanical stimuli

18. The best magneto-hydrodynamic drive for high electrical permittivity fluids

19. The electrical and thermodynamic properties of Boson particles, whose quantum nature is responsible for laser radiation

Suggested by Lumiere PhD mentors at Johns Hopkins University, Cornell University, and Harvard University.

Topic #7 : Quantum properties and theories

Quantum physics studies science at the most fundamental level , and there are many questions yet to be answered. Although there have been recent breakthroughs in the quantum physics field, there are still many undiscovered sub areas that you can explore. These are possible quantum physics research topics:

20. The recent theoretical and experimental advances in the quantum computing field (such as Google’s recent breakthrough result) and explore current high impact research directions for quantum computing from a hardware or theoretical perspective

21. Discovery a new undiscovered composite particle called toponium and how to utilize data from detectors used to observe proton collisions for discoveries

22. Describing a black hole and its quantum properties geometrically as a curvature of space-time and how studying these properties can potentially solve the singularity problem

Suggested by Lumiere PhD mentors at Stanford University, Purdue University, University of Cambridge, and Cornell University.

Topic #8 : Renewable energy and climate change solutions

Climate change is an urgent issue , and you can use physics to research environmental topics ranging from renewable energies to global temperature increases . Some ideas of environmentally related physics research topics are:

23. New materials for the production of hydrogen fuel

24. Analysis of emissions involved in the production, use, and disposal of products

25. Nuclear fission or nuclear fusion energy as possible solutions to mitigate climate change

Suggested by Lumiere PhD mentors at Northwestern University and Princeton University.

If you are passionate or even curious about physics and would like to do research and learn more, consider applying to the Lumiere Research Scholar Program , which is a selective online high school program for students interested in researching with the help of mentors. You can find the application form here .

Rachel is a first year at Harvard University concentrating in neuroscience. She is passionate about health policy and educational equity, and she enjoys traveling and dancing.

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What Are the Interesting Research Topics for High School Physics?

High School Invention Project Ideas

As a subject area, physics is rife with fascinating ideas and principles that offer interesting topics for research projects. Physics offers many opportunities for experimental design and visual representations, along with more traditional products to share what you've learned.

Projectile Motion Projects

Projectile motion is an interesting research topic because objects being thrust through space appear to have some sort of force acting upon them. However, whether an object is dropped, thrown or shot, a projectile is moving through space under the force of gravity. Forensic science uses Newton’s laws of motion to investigate crime scenes for bullet trajectory paths to determine angles from which firearms were discharged. Researching projectile motion as it relates to crime scene investigation offers many fascinating and options for creative high school projects with real-world applications.

Feeling Friction's Effects

Whether a famous actor slides across the floor wearing socks, an oversized button-down and a pair of briefs while lip-synching a rock 'n' roll song, or a twentysomething superstar races a hot rod down a dry, concrete riverbed under a bridge, friction is at play. The force that resists the motion is known as friction. Studying friction and its effects on everyday motion or famous scenes in movies can bring a research project to life. Determining the cause and effects of friction can result in a stimulating physics presentation.

Electronic Circuit Theory

Society as a whole relies on electricity in all its wonder. Learning the how and why of it all is a riveting research topic for high school students. Whether illustrating Ohm’s law and determining how to calculate an electric charge or determining which circuit conducts electricity using the superposition method, electronic circuit theory sparks an interest in the physics-minded student. Fantastic visual and auditory projects can be created using the principles of electronic circuit theory and this can create a fascinating presentation.

Optics and Reflection

Experimenting with the way rays of light are reflected in mirrors, glass or pools of water present interesting fodder for a high school research project. Laser beams, flashlights and sunshine can all be shined upon mirrored surfaces to determine the course of beams of light. The physics behind the motion of the beam and the way the human eye processes an image and a reflected image offer the opportunity for students to create a wide variety of experiments and diagrams to illustrate the theories about light and its properties.

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Christy Maxwell began writing professionally in 2009. She contributes to faith-based publications and writes content for several web-based companies. A National Board Certified special education teacher, Christy is considered an expert in education, writing everything from curriculum to short stories. She holds a Bachelor of Science in counseling from Old Dominion University and a Master of Science in education from William Carey College.

416 Physics Topics & Ideas to Research

18 January 2024

last updated

Physics topics may include the complex systems of the universe, from the smallest particles to colossal galaxies. This field of study examines fundamental concepts, such as force, energy, and matter, extrapolating them into areas like quantum or relative mechanics. It also explores thermodynamics, revealing the intriguing principles behind heat, work, and energy conversions. Some themes may vary from the mysteries of dark matter and energy in cosmology to the resonating string theories in theoretical physics. Moreover, the world of semiconductors in solid-state physics presents a spectrum of interconnected topics. In turn, the essential laws of physics provide the basis for almost all scientific research, offering profound insights into the natural world and shaping human understanding of how everything in the universe behaves and interacts.

Cool Physics Topics

Quantum Entanglement and Its Potential Applications
Harnessing Solar Energy: Next-Generation Photovoltaic Cells
Plasma Physics and Controlled Fusion Energy
The Role of Physics in Climate Change Models
Dark Matter and Dark Energy: Unveiling the Universe’s Mysteries
Astrophysics: Formation and Evolution of Black Holes
Implications of Superconductivity in Modern Technology
Roles of Biophysics in Understanding Cellular Mechanisms
Theoretical Physics: The Quest for Quantum Gravity
Nanotechnology: Manipulating Matter at the Atomic Scale
Cosmic Microwave Background Radiation and the Big Bang Theory
The Uncertainty Principle and Its Philosophical Consequences
Exploring Exoplanets: Physics Beyond Our Solar System
Advances in Optics: From Microscopy to Telecommunications
Gravitational Waves: Probing the Fabric of Spacetime
Neutrino Physics: Studying the Universe’s Ghost Particles
Entropy and Time’s Arrow: Understanding Thermodynamics
Applications of Particle Physics in Medicine
Physics of Semiconductors and the Evolution of Computing
Exploring String Theory and Multidimensional Realities
Relativity Theory: Spacetime Curvature and Gravitational Lenses
Quantum Computing: Bridging Physics and Information Technology

Easy Physics Topics

Antimatter: Understanding its Properties and Possible Uses
Physics of Chaos and Nonlinear Dynamical Systems
Condensed Matter Physics: Unveiling the Behavior of Phases of Matter
Science of Acoustics: Understanding Sound Phenomena
Roles of Physics in Developing Advanced Materials
Synchrotron Radiation: Tools and Techniques in Research
Particle Accelerators: Probing the Quantum World
Theoretical Predictions and Experimental Tests in Quantum Mechanics
Nuclear Fusion: The Physics of a Star’s Energy Production
The Holographic Principle: A Revolution in Quantum Physics?
Biomechanics: Understanding the Physics of Life Movements
Exploring the Physics of Supermassive Black Holes
Magnetism: From Quantum Spin to Industrial Applications
Laser Physics: Principles and Cutting-Edge Applications
Advances in Cryogenics and Low-Temperature Physics
The Physics of Flight: From Birds to Airplanes
Quantum Field Theory and the Nature of Reality
Modern Cosmology: Inflation and the Cosmic Structure
Probing Subatomic Particles in High-Energy Physics
Physics of Fluid Dynamics: From Blood Flow to Weather Systems
The Grand Unified Theory: Bridging Fundamental Forces
Quantum Cryptography: Ensuring Information Security
Photonic Crystals and Their Applications in Telecommunication

Physics Research Paper Topics for High School

Exploring the Mysteries of Dark Matter and Dark Energy
Quantum Entanglement: Unraveling the Enigma
Nanotechnology: The Physics of the Incredibly Small
Black Holes: Understanding Gravity’s Ultimate Victory
Time Travel: Exploring its Possibility in Physics
Particle Physics: A Closer Look at the Higgs Boson
Waves and Resonance: The Science Behind Vibrations
Antimatter: The Mirror Image of Normal Matter
Superconductivity: Exploring the Role of Temperature
Effects of Nuclear Physics on Medical Imaging Technology
The Theory of Everything: Unifying the Fundamental Forces
Superstring Theory: The Quest for Unification
Chaos Theory: A Journey Through Nonlinear Dynamics
Radioactivity: The Science Behind Nuclear Decay
Examining the Physical Properties of Non-Newtonian Fluids
Magnetic Monopoles: A Missing Piece in Electromagnetism?
Quantum Field Theory: The World of Subatomic Particles
Physics of Climate Change: Understanding Global Warming
Thermodynamics: The Science of Heat and Energy Transfers

Physics Research Paper Topics for College Students

Unveiling the Mysteries of Quantum Entanglement
Implications of Zero-Point Energy: A Look Into Vacuum Fluctuations
Examining the Principles and Potential of Nuclear Fusion
Harnessing Antimatter: Theoretical Approaches and Practical Limitations
Tracing Cosmic Rays: Sources, Propagation, and Interaction with Matter
Advanced Gravitational Waves: Detection and Significance
Rethinking Dark Matter: Contemporary Views and Hypotheses
Probing Planetary Physics: Dynamics in Our Solar System
Exploring the Physics of Black Holes: Beyond the Event Horizon
Thermodynamics in Nanoscale Systems: Deviations From Classical Rules
Computational Physics: The Impact of Machine Learning on Physical Research
Spintronics: Revolutionizing Information Technology
Accelerators in Medicine: Using Particle Physics for Cancer Treatment
The Influence of Physics on Climate Change Modeling
Neutrino Oscillations: Exploring the Ghost Particles
Quantum Computing: Bridging the Gap Between Physics and Information Technology
Dark Energy and the Accelerating Universe: Current Understanding
Gauge Theories in Particle Physics: A Deep Dive
The Holographic Principle: The Universe as a Hologram
The Role of Physics in Renewable Energy Technologies
Time Travel Theories: Fact or Fiction?
Implications of String Theory in Modern Physics

Physics Research Paper Topics for University

Metamaterials: Creating the Impossible in Optics and Acoustics
Fluid Dynamics in Astrophysics: Stars, Galaxies, and Beyond
Tackling Turbulence: The Last Great Problem in Classical Physics
The Casimir Effect: Unearthing Quantum Force in the Vacuum
Superconductivity: New Frontiers and Applications
Advances in Biophysics: Cellular Mechanisms to Organismal Systems
The Physics of Spacecraft Propulsion: Ion Drives and Beyond
Supersymmetry: The Unfulfilled Promise of the Universe
Relativity and GPS: The Unseen Influence of Physics in Everyday Life
Topological Insulators: Quantum Phenomena in Solid State Physics
The Future of Photonics: Powering the Next Generation of Technology
Atomic Clocks: The Intersection of Quantum Mechanics and Relativity
Quantum Field Theory: A Modern Understanding
Electromagnetism in Biological Systems: Understanding Bioelectricity
The Kardashev Scale: A Framework for Advanced Civilizations
Harnessing the Sun: The Physics of Solar Energy
M-Theory: The Unifying Theory of Everything
Bell’s Theorem: Debunking Local Realism
Quantum Cryptography: Security in the Age of Quantum Computers
Geophysics: Understanding the Earth’s Core and Plate Tectonics

Physics Research Paper Topics for Master’s & Ph.D.

Quantum Entanglement: Unraveling the Spooky Action at a Distance
Harnessing Fusion Power: Prospects for Unlimited Clean Energy
Gravitational Waves: Detecting Ripples in Spacetime
The Nature of Black Holes and Singularities
Time Dilation and Its Applications in Modern Physics
Investigating the Particle-Wave Duality: A Deeper Look Into Quantum Mechanics
The Physics of Superconductors: Transitioning From Theory to Practical Applications
Hawking Radiation: From Theory to Possible Observations
Evolution of the Universe: A Closer Look at the Big Bang Theory
Exploring the Higgs Field: Implications for Particle Physics
Nanotechnology in Physics: The Promising Path Toward the Future
String Theory and the Quest for a Theory of Everything
The Role of Physics in Climate Change Modelling
Understanding Neutrinos: Ghost Particles of the Universe
The Fundamentals of Chaos Theory: Applications in Modern Physics
Quantum Computing: Breaking Down the Physics Behind the Future of Computation
Exploring The Fourth Dimension: A Journey Beyond Time
Astrophysics and the Study of Exoplanets: Seeking Alien Life
Quantum Field Theory: Bridging Quantum Mechanics and Special Relativity
Understanding Quantum Tunneling: Applications and Implications
Study of Quarks: Subatomic Particles and the Strong Force
Biophysics and the Mechanics of Cellular Structures
Magnetic Monopoles: Hunting for the Missing Entities in Quantum Theory

Physics Research Topics on Classical Mechanics

Understanding Kepler’s Laws and Their Practical Applications
The Role of Energy Conservation in Mechanical Systems
Implications of Newton’s Third Law on Engineering Designs
Exploring Oscillatory Motion: Springs and Pendulums
Effects of Friction Forces on Everyday Objects
Stability of Rotational Systems in Aerospace Engineering
Interpreting Physical Phenomena Using Vector Mechanics
Influence of Classical Mechanics on Modern Architecture
Application of Momentum Conservation in Collision Analysis
Kinematics of Complex Systems: An In-Depth Study
Elasticity and Its Impact on Material Science
Newtonian Physics in Contemporary Game Design
The Art of Fluid Dynamics: Concepts and Applications
Gyroscopes and Their Applications in Modern Technologies
Applications of Torque in Mechanical Engineering
Relevance of Angular Momentum in Astrophysics
The Science Behind Musical Instruments: A Mechanical Perspective
Diving Into the Parallels Between Classical and Quantum Mechanics
Exploring Parabolic Trajectories in Projectile Motion
Dynamics of Multi-Body Systems in Space Exploration

Research Topics for Physics of Materials

Analysis of Quantum Behavior in Superconductors
Predictive Modelling of Phase Transitions in Crystalline Structures
Examination of Electron Mobility in Semi-Conductive Materials
Study of High-Temperature Superconductivity Phenomena
Mechanical Properties of Novel Metallic Alloys
Graphene: Exploring its Remarkable Electronic Properties
Optimization of Energy Storage in Advanced Battery Materials
Ferroelectric Materials: Unraveling their Unique Electrical Properties
Assessing Durability of Construction Materials Under Environmental Stressors
Properties and Potential Applications of Topological Insulators
Investigation into Multiferroic Materials: Challenges and Opportunities
Dynamic Response of Materials under High-Strain Rates
Nanomaterials: Understanding Size-Dependent Physical Properties
Harnessing Thermoelectric Materials for Energy Conversion
Photonic Crystals: Manipulation of Light Propagation
Exploring Amorphous Solids: From Metallic Glasses to Plastics
Investigations into Magnetocaloric Materials for Eco-Friendly Refrigeration
Neutron Scattering in the Study of Magnetic Materials
Probing the Anisotropic Nature of Composite Materials
Characterization of Disordered Materials Using Spectroscopic Techniques
Roles of Surface Physics in Material Science

Physics Research Topics on Electrical Engineering

Influence of Artificial Intelligence on Modern Power Systems
Radio Frequency Identification (RFID): Advancements and Challenges
Improving Transmission Efficiency Through Smart Grids
Developments in Electric Vehicle Charging Infrastructure
Optical Fiber Technology: The Future of Communication
Interplay between Solar Power Engineering and Material Science
Harnessing the Potential of Superconductors in Electrical Engineering
Li-Fi Technology: Lighting the Way for Data Communication
Innovations in Energy Storage: Beyond Lithium-Ion Batteries
Designing Efficient Power Electronics for Aerospace Applications
Exploring the Boundaries of Microelectronics With Quantum Dots
Robotic Automation: Electrical Engineering Perspectives
Power System Stability in the Era of Distributed Generation
Photovoltaic Cells: Advances in Efficiency and Cost-Effectiveness
Investigating the Feasibility of Wireless Power Transfer
Unmanned Aerial Vehicles (UAVs): Power Management and Energy Efficiency
Quantum Entanglement: Implications for Information Transmission
Fuel Cells: Exploring New Frontiers in Electrical Power Generation
Machine Learning Applications in Predictive Maintenance of Electrical Systems
Neural Networks and their Role in Electrical Circuit Analysis

Optical Physics Research Topics

Exploring Quantum Optics: Unveiling the Peculiarities of Light-Particle Interactions
Harnessing the Power of Nonlinear Optics: Potential Applications and Challenges
Fiber Optic Technology: Influencing Data Transmission and Telecommunication
The Role of Optics in Modern Telescopic Innovations: An Analytical Study
Polarization of Light: Understanding the Physical and Biological Applications
Unfolding the Mystery of Optical Tweezers: Manipulation and Measurement at the Microscale
Lasing Mechanisms: Insights Into the Evolution and Operation of Lasers
Waveguides and Their Crucial Role in Integrated Optics: A Comprehensive Study
Optical Illusions: Revealing the Underlying Physics and Perception Aspects
Biophotonics: The Intersection of Optics and Biomedicine
Exploiting Optical Metamaterials: The Pathway to Invisible Cloaking Devices
Optical Holography: Unearthing the Potential for 3D Visualization and Display Systems
Investigation of Optical Solitons: Nonlinear Pulses in Fiber Optic Communications
Plasmonics: Harnessing Light With Nanostructures for Enhanced Optical Phenomena
Advances in Spectroscopy: Optical Techniques for Material Analysis
The Physics behind Optical Coherence Tomography in Medical Imaging
Optical Vortices and Their Role in High-Capacity Data Transmission
Ultrafast Optics: Time-Resolved Studies and Femtosecond Laser Applications
In-Depth Review of Optical Trapping and Its Potential in Nanotechnology
Optical Parametric Oscillators: Applications in Spectroscopy and Laser Technology
Theoretical Perspectives on Photonic Crystals and Band Gap Engineering

Physics Research Topics on Acoustics

Exploration of Ultrasonic Waves in Medical Imaging and Diagnostics
Propagation of Sound in Various Atmospheric Conditions
Impacts of Acoustics on Architectural Design Principles
Innovative Approaches to Noise Cancellation Technologies
The Role of Acoustics in Underwater Communication Systems
Sonic Boom Phenomena: Causes and Effects
Effects of Acoustic Resonance in Musical Instruments
Influence of Material Properties on Sound Absorption
Harnessing the Power of Sound: Acoustic Levitation Research
Relationship Between Acoustic Ecology and Urban Development
Evaluating the Principles of Acoustic Metamaterials
Acoustic Thermometry: Precision in Temperature Measurement
Potential Applications of Phononic Crystals in Acoustics
Deciphering Dolphin Communication: Bioacoustics in Marine Life
Development and Improvement of Acoustic Emission Techniques
Thermoacoustic Engines and Refrigeration: An Emerging Technology
Investigating the Psychoacoustic Properties of Sound
Impacts of Acoustic Treatment in Home Theatres and Studios
Evaluating the Effectiveness of Sonar Systems in Submarine Detection
Ultrasound Applications in Non-Destructive Testing and Evaluation

Physics Research Topics on Thermodynamics

Investigating the Role of Thermodynamics in Nanotechnology Development
Entropy Production: A Deep Dive into Non-Equilibrium Thermodynamics
Impacts of Thermodynamics on Energy Conservation Practices
Quantum Thermodynamics: Bridging Quantum Mechanics and Traditional Thermodynamics
Advanced Materials in Heat Engines: A Thermodynamic Perspective
Applications of Thermodynamics in Renewable Energy Technology
Exploring Thermodynamic Limits of Computation: Theoretical and Practical Aspects
Unveiling the Mysteries of Black Hole Thermodynamics
Influence of Thermodynamics in Climate Change Modelling
Exploiting Thermodynamics for Efficient Spacecraft Heat Management
Understanding Biological Systems Through the Lens of Thermodynamics
Applying Thermodynamics to Predict Geophysical Phenomena
Thermodynamics in Food Processing: Effects on Nutrient Preservation
Biogeochemical Cycles: An Insight From Thermodynamics
Roles of Thermodynamics in Understanding Supernova Explosions
Thermodynamics in Modern Architecture: Energy-Efficient Building Designs
Thermoelectric Materials: Harnessing Thermodynamics for Power Generation
Roles of Thermodynamics in Efficient Resource Recovery From Waste
Thermodynamics and Its Implications in the Formation of Stars
Exploring Thermodynamics in Quantum Information Theory

Particle Physics Research Topics

Unraveling the Mysteries of Quark Structures in Baryonic Matter
The Enigma of Neutrino Oscillations: New Discoveries
String Theory Applications in Particle Physics: A New Horizon
Dark Matter Particles: Unseen Influences on Cosmic Structures
The Higgs Field and Its Implications for the Standard Model
Lepton Family: A Comprehensive Study of Their Unique Properties
Quantum Chromodynamics: Decoding the Strong Force
The Role of W and Z Bosons in Electroweak Interactions
Antiparticle Behavior and Its Ramifications for Symmetry
Detecting Supersymmetry: A Paradigm Shift in Particle Physics?
Insights Into Graviton: Hunting the Quantum of Gravity
Probing the Exotic: Search for Hypothetical Particles
Flavor Changing Processes in the Quark Sector: An Analytical Approach
Precision Measurements of the Top Quark: A Key to New Physics
Pentaquark Particles: A Fresh Perspective on Hadronic Matter
Examining the Asymmetry Between Matter and Antimatter
Gluons and Confinement: Probing the Fabric of Quantum Chromodynamics
Proton Decay: GUTs, Supersymmetry, and Beyond
Unveiling the Secrets of Cosmic Ray Particles
Meson Spectroscopy: Understanding Hadrons Better
Scalar Fields and Inflation: A Quantum Field Theory Perspective

Statistical Physics Research Topics

Exploring the Second Law of Thermodynamics in Cosmic Evolution
Investigating the Role of Entropy in the Black Hole Information Paradox
Understanding Statistical Mechanics in Biophysical Systems
Analyzing Temperature’s Impact on Quantum Spin Chains
Diving Into Phase Transitions in Quantum Fields
Quantum Fluctuations and Their Statistical Significance
Applications of Statistical Physics in Neural Networks
Investigating the Universality Classes in Critical Phenomena
Revealing the Role of Statistical Physics in Ecosystem Dynamics
Fluctuation Theorems: A Study of Non-Equilibrium Systems
Statistical Physics’ Approach to Understanding Traffic Flow Dynamics
Non-Equilibrium Statistical Mechanics in Living Systems
Deciphering the Puzzle of Quantum Entanglement Using Statistical Methods
Research on Spin Glasses and Disorder in Statistical Physics
Thermodynamics in Small Systems: A Statistical Physics Approach
Fractal Analysis: Its Impact on Statistical Physics
Harnessing the Power of Statistical Physics for Climate Modeling
Introducing Quantum Field Theory to Statistical Physics Studies
Investigating Energy Landscapes in Protein Folding
Simulating Turbulence Using Concepts of Statistical Physics

Atomic Physics Research Topics

Quantum Entanglement and Its Impact on Information Transfer
Exploring the Properties of Exotic Atoms
Manipulating Matter: The Potential of Cold Atoms
Unveiling the Secrets of Quantum Decoherence
Probing Quantum Tunneling: From Theory to Practical Applications
Atomic Collisions and Their Consequences in Astrophysics
Advancements in Atomic Clock Technology and Precision Timekeeping
Harnessing the Power of Quantum Computing With Atomic Physics
Advancements in Atom Interferometry and Precision Measurements
Evaluating the Influence of Atomic Physics on Biological Systems
Atomic Physics Applications in Emerging Technologies
Unlocking the Mysteries of Atomic Spectroscopy
Delving into the World of Ultracold Atoms and Bose-Einstein Condensates
The Role of Atomic Physics in Climate Change Studies
Shedding Light on Dark Matter: Atomic Physics Approaches
Innovations in Controlled Nuclear Fusion Through Atomic Physics
Electron Capture and Beta Decay: The Intricacies of Weak Force
Quantum Magnetism and Its Influence on Atomic Structures
Theoretical Frameworks for Describing Atomic Structure and Behavior
The Future of Nanotechnology: Role of Atomic Physics
Understanding Atomic Physics Role in Quantum Cryptography
Fundamental Symmetries: Atomic Physics Perspectives and Tests

Physics Research Topics on Quantum Mechanics

Investigating the Quantum Behavior of Superconducting Circuits
Exploring the Applications of Quantum Entanglement in Communication Systems
Analyzing the Role of Quantum Mechanics in Biological Systems
Developing Quantum Algorithms for Solving Complex Optimization Problems
Understanding Quantum Tunneling in Nanostructures
Investigating Quantum Coherence in Macroscopic Systems
Exploring the Role of Quantum Mechanics in Quantum Computing
Analyzing the Quantum Properties of Photons in Quantum Information Processing
Developing Quantum Sensors for High-Precision Measurements
Investigating the Quantum Mechanics of Quantum Dots in Optoelectronic Devices
Analyzing the Quantum Mechanics of Spintronics for Information Storage and Processing
Exploring the Role of Quantum Mechanics in Quantum Cryptography
Investigating the Quantum Properties of Bose-Einstein Condensates
Developing Quantum Simulators for Studying Complex Quantum Systems
Analyzing the Quantum Mechanics of Topological Insulators
Exploring Quantum Chaos and its Applications in Quantum Mechanics
Investigating the Quantum Mechanics of the Quantum Hall Effect
Analyzing the Quantum Properties of Quantum Gravity
Exploring the Role of Quantum Mechanics in Quantum Sensing and Metrology
Investigating the Quantum Mechanics of Quantum Optics

Nuclear Physics Research Topics

Quantum Tunneling in Nuclear Reactions
Neutron Stars: Structure and Properties
Nuclear Fusion as a Clean Energy Source
Investigating the Role of Mesons in Nuclear Forces
Nuclear Shell Model: Understanding Nucleus Stability
Proton-Proton Collisions in High-Energy Physics
Nuclear Fission: Mechanisms and Applications
Theoretical Analysis of Nuclear Decay Processes
Particle Accelerators for Nuclear Physics Research
The Quark-Gluon Plasma: Experimental Studies
Superheavy Elements and Their Synthesis
Nuclear Magnetic Resonance Spectroscopy in Materials Science
Neutrino Oscillations and Mass Hierarchy
Isotope Separation Techniques for Medical and Industrial Applications
Exotic Nuclear Shapes: Triaxial and Hyperdeformed Nuclei
Nuclear Data Evaluation and Uncertainty Analysis
Studying Nuclear Reactions in Supernovae
Exploring Nuclear Isomerism for Quantum Computing
Nuclear Waste Management and Disposal Strategies
Giant Resonances in Nuclear Physics

Physical Geography Topics to Write About

Solar Radiation’s Impact on Geographical Landform Evolution
Oceanic Currents and Their Role in Coastal Erosion
Atmospheric Pressure Interactions and Mountain Formation
Tectonic Plate Movements’ Influence on Geographical Features
Gravity’s Contribution to Geographical Landscape Formation
Climate Change Effects on Glacial Retreat and Polar Geography
Wind Patterns and Dune Formation in Deserts
River Networks’ Dynamics and Fluvial Geomorphology
Volcanic Activity and Island Formation
Magnetic Fields and Geomagnetic Reversals in Paleomagnetism
Earthquakes’ Impact on Geographical Landforms and Seismic Hazards
Rainfall Patterns and Soil Erosion in Agricultural Landscapes
Geothermal Energy’s Role in Hydrothermal Features
Tsunamis’ Effects on Coastal Landforms and Human Settlements
Earth’s Magnetic Field and the Auroras
Eolian Processes and Desertification in Arid Landscapes
Gravity Waves’ Influence on Atmospheric Circulation and Climate Patterns
River Diversions and Delta Formation
Climate Change and Coral Reef Degradation
Ice Sheets’ Dynamics and Sea Level Rise
Karst Processes and Cave Formation

Astrophysics Topics for a Research Paper

Quantum Effects in Stellar Evolution
Gravitational Waves From Binary Neutron Star Mergers
Cosmic Microwave Background Anisotropy Analysis
Supernova Nucleosynthesis and Element Formation
Dark Matter Distribution in Galaxy Clusters
Magnetic Fields in Protostellar Disks
Exoplanet Atmospheres and Habitability
Black Hole Dynamics in Galactic Centers
High-Energy Particle Acceleration in Active Galactic Nuclei
Gamma-Ray Burst Progenitor Identification
Interstellar Medium Turbulence and Star Formation
Neutrino Oscillations in Supernova Explosions
Cosmic Ray Propagation in the Galactic Magnetic Field
Stellar Populations and Galactic Archaeology
Stellar Pulsations and Variable Stars in Globular Clusters
Dusty Torus Structure in Active Galactic Nuclei
Planetary Formation in Binary Star Systems
Primordial Magnetic Fields and Early Universe Magnetogenesis
Neutron Star Equation of State Constraints from Pulsar Timing
Galactic Chemical Evolution and Metal Enrichment

Theoretical Physics Topics to Research

Quantum Entanglement in Multi-Particle Systems
Gravitational Waves and Black Hole Mergers
Emergent Phenomena in Condensed Matter Physics
Nonlinear Dynamics and Chaos in Physical Systems
Symmetry Breaking and Phase Transitions
Topological Insulators and Their Applications
Quantum Computing and Information Theory
Cosmological Inflation and the Early Universe
Quantum Field Theory and Particle Interactions
Time Reversal Symmetry in Quantum Mechanics
Black Hole Thermodynamics and Hawking Radiation
Quantum Simulation and Quantum Many-Body Systems
Dark Matter and Its Detectability
Superconductivity and Superfluidity
Information-Theoretic Approaches to Quantum Gravity
Magnetic Monopoles and Their Role in Particle Physics
High-Energy Physics and Collider Experiments
Quantum Hall Effect and Topological Order
Quantum Optics and Quantum Information Processing
Neutrino Physics and Neutrino Oscillations
Fractals and Self-Similarity in Physical Systems

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12 Physics Passion Project Ideas For High School Students

By Alex Yang

Graduate student at Southern Methodist University

7 minute read

Physics, often described as the science that reveals the mysteries of the universe, can be especially interesting for those who are curious about the world around them. Physics has an incredible range of applications, from the smallest subatomic particles to the vast cosmic expanses, from the intricate mechanics of a clock to the power of a black hole. As a result, knowledge of physics can help with careers in engineering, astronomy, environmental science, and even finance.

In this article, we’ll discuss ideas for different physics research and passion projects high school students can take on and different ways to showcase your project.

Finding Your Physics Passion Project Focus

There are many different directions you can take with your physics passion project, so take some time to think through what specific topics within physics you’re interested in. Maybe you’re more interested in physics’ applications for space exploration, or perhaps you’re more intrigued by the movements of humans or animals, or the aerodynamics of specific objects. If you find yourself in a position where you have a direction that interests you, great! You can then begin to dive deeper.

Keep in mind that some physics passion projects may require more technical skills like coding or measurement of data, whereas others may just explore theoretical concepts. The route you take is totally up to you and what you feel comfortable with, but don’t be afraid to pursue a project if you don’t currently have the technical skills for it! You can view it as an opportunity to learn new skills while also exploring a topic you’re excited about.

12 Physics Research and Passion Projects Ideas

Learn the basics of how lasers work! After studying the basics of optical resonators, you can learn more about a particular type of laser (such as a semiconductor or helium-neon laser) and explain what makes it tick, and what its particular advantages and disadvantages are.

Idea by physics research mentor Christian

2. Knot theory and topology

Knot theory is a branch of mathematics that studies knots. There is a rich mathematical structure involving knots. It turns out that you cannot deform any particular knot into another knot (some knots are permanently tangled) - this is called a "topological obstruction." In this project, you would learn about topology in the context of knot theory . No formal knowledge of math is required to study knot theory!

Idea by physics research mentor Adam

3. Hijacking physics to do math for us

We use math to do a lot of things, like run computers or make predictions. We also use math to describe physical behaviors in the world. In a sense, the world around us is constantly doing "calculations" with physics. In this project, we'll figure out a way to get the world to do our math for us, either in simulation or a simple physical system. Pick an example task (e.g., measure vibration/seismic activity over time, sense changes in shape, detect humidity), and figure out how to make a reliable test without using a computer. Think about experimental design, dealing with the noisiness of the real world, and critical data analysis.

Idea by physics research mentor Sam

4. Physics of dance

Do you love dance and physics? How can you describe the art form through physics concepts? For example, how can you investigate and explain the "physics of a pirouette"?

Idea by physics research mentor Calli

5. Wait, it flies as well?

Snakes, Spiders, Squid! What do all these animals have in common? All of these animals "fly" in the loosest sense. There are species of snakes that glide, species of spiders that balloon and squid can jet out of the water! This project would look at existing literature to determine how these animals are able to "fly" and what about them makes them different from their air/land restricted siblings.

Idea by physics research mentor Theodore

6. Determining optimal manufacturing methods for airplanes

Airplane wings are made from all types of materials, but how can engineers determine the optimal material for their specific design? In order to determine the answer, we need to figure out what the connection is between the aerodynamics of the wing and the strength of the materials. In this project, students will ideally experimentally build and test multiple wing design prototypes to determine an optimal manufacturing method. This project is perfect for you if you’re interested in more hands-on work!

Idea by physics research mentor George

7. Analysis of low-thrust trajectories for space exploration

In this project, your goal would be to investigate the trade-off between thrust and specific impulse (e.g., fuel efficiency) for propulsion on different space missions. You can first perform a literature review of the relevant types and key physics of spacecraft propulsion . This work could then consider the benefits and drawbacks of various space power systems, including solar and nuclear power. Your final project outcome could include analysis of the trade-offs between required fuel mass, travel time, and other relevant factors.

Idea by physics research mentor Parker

Work with an expert mentor to explore your passion

At Polygence, we precisely match you with a mentor in your area of interest. Together, you can explore and deepen your passions.

8. Why are geckos' feet special?

Walking on walls and ceilings isn't just a superpower from Spider-Man – geckos and even houseflies are able to go where no human can. Through experimentation and literature studies, this project investigates the nano-physical concept of "adhesion" to demonstrate why geckos have these unique abilities.

9. How is the James Webb Space Telescope changing astronomy?

The James Webb Space Telescope (Webb) is a infrared space telescope, launched at the end of 2021, that is currently providing us with a massive amount of new information about our galaxy thanks to its high-resolution and high-sensitivity instruments. This project would take a deep dive into the kinds of data we are getting back from the telescope and what scientists are doing with that data - leading us to discover how Webb is shifting current astronomical studies and what that means for the future of astronomy.

Idea by physics research mentor Madeline

10. Rigid body dynamics

Rigid body dynamics studies how rigid objects behave as they are acted on by forces, such as when they collide with each other. This was one of the first things Pixar had to simulate when making Toy Story and it is actually an active field of research at Disney today. In this project, you will explore the mathematical methods of rigid body dynamics and develop your own program to simulate balls bouncing off a plane. This resource from Khan Academy is a great place to start exploring rigid body systems.

Idea by physics research mentor Ina

11. Characterizing gait types of household pets

At what point does a dog's movement transition from a walk to a run? What stride length and frequency do they use when walking vs. when running? For what portion of a single gait cycle are just two limbs on the ground? Questions like these could be explored with household pets or insects from your backyard using your phone's camera, some motion tracking software, and some basic coding.

Idea by physics research mentor Brooke

12. Mountains from another dimension

Mountain ranges tend to have "fractal" surfaces; you can sometimes see these "finger-like" ridge lines splitting away from a peak and descending down. Fractals can famously have dimensions in between the usual 2 or 3 dimensions we are used to. You could use publicly available elevation data to measure the "fractal dimension" of a mountain range. Does the fractal dimension tell us something about the topography or geology of the mountain range?

Idea by physics research mentor Anoop

How to Showcase Your Physics Passion Project

After you’ve done the hard work of researching and learning physics concepts, it’s also equally important to decide how you want to showcase your project . You can see that in many of the project ideas above, there is a clear topic, but how you want to present the project is open-ended. You could try to publish a research paper , create a podcast or infographic, or even create a visual representation of your concept. You’ll find that although many project ideas may feel like they should just be summarized in a paper, many actually can be showcased creatively in another way!

Examples of Physics Passion Projects Completed by Polygence Students

There are several examples of amazing physics passion projects completed by Polygence students . We encourage you to explore them for inspiration; we’ll highlight two here:

Arif’s project was a research paper on nuclear fission reactor moderators , where he looked to find the best and most feasible compounds to achieve a chain reaction with maximum efficiency.

Carl’s project was creating an online physics calculator that solves physics equations and shows the steps to arrive at the solution. The calculator is on a website where physics students can learn about complex equations and learn step by step.

Moving Forward With Your Physics Project

In this article, we covered how to find the right physics project for you, shared a dozen ideas for physics passion projects, and discussed how to showcase your project.

If you have a passion or even just a curiosity about physics and you’re interested in pursuing a passion project, Polygence’s programs are a great place to start. You’ll be able to meet virtually one-on-one with a physics research mentor who can help you learn new concepts and brainstorm with you on ways to showcase your passion project .

Want to start a project of your own?

Click below to get matched with one of our expert mentors who can help take your project off the ground!

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Home » 500+ Physics Research Topics

500+ Physics Research Topics

Table of Contents

Physics is the study of matter, energy, and the fundamental forces that govern the universe. It is a broad and fascinating field that has given us many of the greatest scientific discoveries in history , from the theory of relativity to the discovery of the Higgs boson. As a result, physics research is always at the forefront of scientific advancement, and there are countless exciting topics to explore. In this blog post, we will take a look at some of the most fascinating and cutting-edge physics research topics that are being explored by scientists today. Whether you are a student, researcher, or simply someone with a passion for science, there is sure to be something in this list that will pique your interest.

Physics Research Topics

Physics Research Topics are as follows:

Physics Research Topics for Grade 9

Investigating the properties of waves: amplitude, frequency, wavelength, and speed.
The effect of temperature on the expansion and contraction of materials.
The relationship between mass, velocity, and momentum.
The behavior of light in different mediums and the concept of refraction.
The effect of gravity on objects and the concept of weight.
The principles of electricity and magnetism and their applications.
The concept of work, energy, and power and their relationship.
The study of simple machines and their efficiency.
The behavior of sound waves and the concept of resonance.
The properties of gases and the concept of pressure.
The principles of heat transfer and thermal energy.
The study of motion, including speed, velocity, and acceleration.
The behavior of fluids and the concept of viscosity.
The concept of density and its applications.
The study of electric circuits and their components.
The principles of nuclear physics and their applications.
The behavior of electromagnetic waves and the concept of radiation.
The properties of solids and the concept of elasticity.
The study of light and the electromagnetic spectrum.
The concept of force and its relationship to motion.
The behavior of waves in different mediums and the concept of interference.
The principles of thermodynamics and their applications.
The study of optics and the concept of lenses.
The concept of waves and their characteristics.
The study of atomic structure and the behavior of subatomic particles.
The principles of quantum mechanics and their applications.
The behavior of light and the concept of polarization.
The study of the properties of matter and the concept of phase transitions.
The concept of work done by a force and its relationship to energy.
The study of motion in two dimensions, including projectile motion and circular motion.

Physics Research Topics for Grade 10

Investigating the motion of objects on inclined planes
Analyzing the effect of different variables on pendulum oscillations
Understanding the properties of waves through the study of sound
Investigating the behavior of light through refraction and reflection experiments
Examining the laws of thermodynamics and their applications in real-life situations
Analyzing the relationship between electric fields and electric charges
Understanding the principles of magnetism and electromagnetism
Investigating the properties of different materials and their conductivity
Analyzing the concept of work, power, and energy in relation to mechanical systems
Investigating the laws of motion and their application in real-life situations
Understanding the principles of nuclear physics and radioactivity
Analyzing the properties of gases and the behavior of ideal gases
Investigating the concept of elasticity and Hooke’s law
Understanding the properties of liquids and the concept of buoyancy
Analyzing the behavior of simple harmonic motion and its applications
Investigating the properties of electromagnetic waves and their applications
Understanding the principles of wave-particle duality and quantum mechanics
Analyzing the properties of electric circuits and their applications
Investigating the concept of capacitance and its application in circuits
Understanding the properties of waves in different media and their applications
Analyzing the principles of optics and the behavior of lenses
Investigating the properties of forces and their application in real-life situations
Understanding the principles of energy conservation and its applications
Analyzing the concept of momentum and its conservation in collisions
Investigating the properties of sound waves and their applications
Understanding the behavior of electric and magnetic fields in charged particles
Analyzing the principles of thermodynamics and the behavior of gases
Investigating the properties of electric generators and motors
Understanding the principles of electromagnetism and electromagnetic induction
Analyzing the behavior of waves and their interference patterns.

Physics Research Topics for Grade 11

Investigating the effect of temperature on the resistance of a wire
Determining the velocity of sound in different mediums
Measuring the force required to move a mass on an inclined plane
Examining the relationship between wavelength and frequency of electromagnetic waves
Analyzing the reflection and refraction of light through various media
Investigating the properties of simple harmonic motion
Examining the efficiency of different types of motors
Measuring the acceleration due to gravity using a pendulum
Determining the index of refraction of a material using Snell’s law
Investigating the behavior of waves in different mediums
Analyzing the effect of temperature on the volume of a gas
Examining the relationship between current, voltage, and resistance in a circuit
Investigating the principles of Coulomb’s law and electric fields
Analyzing the properties of electromagnetic radiation
Investigating the properties of magnetic fields
Examining the behavior of light in different types of lenses
Measuring the speed of light using different methods
Investigating the properties of capacitors and inductors in circuits
Analyzing the principles of simple harmonic motion in springs
Examining the relationship between force, mass, and acceleration
Investigating the behavior of waves in different types of materials
Determining the energy output of different types of batteries
Analyzing the properties of electric circuits
Investigating the properties of electric and magnetic fields
Examining the principles of radioactivity
Measuring the heat capacity of different materials
Investigating the properties of thermal conduction
Examining the behavior of light in different types of mirrors
Analyzing the principles of electromagnetic induction
Investigating the properties of waves in different types of strings.

Physics Research Topics for Grade 12

Investigating the efficiency of solar panels in converting light energy to electrical energy.
Studying the behavior of waves in different mediums.
Analyzing the relationship between temperature and pressure in ideal gases.
Investigating the properties of electromagnetic waves and their applications.
Analyzing the behavior of light and its interaction with matter.
Examining the principles of quantum mechanics and their applications.
Investigating the properties of superconductors and their potential uses.
Studying the properties of semiconductors and their applications in electronics.
Analyzing the properties of magnetism and its applications.
Investigating the properties of nuclear energy and its applications.
Studying the principles of thermodynamics and their applications.
Analyzing the properties of fluids and their behavior in different conditions.
Investigating the principles of optics and their applications.
Studying the properties of sound waves and their behavior in different mediums.
Analyzing the properties of electricity and its applications in different devices.
Investigating the principles of relativity and their applications.
Studying the properties of black holes and their effect on the universe.
Analyzing the properties of dark matter and its impact on the universe.
Investigating the principles of particle physics and their applications.
Studying the properties of antimatter and its potential uses.
Analyzing the principles of astrophysics and their applications.
Investigating the properties of gravity and its impact on the universe.
Studying the properties of dark energy and its effect on the universe.
Analyzing the principles of cosmology and their applications.
Investigating the properties of time and its effect on the universe.
Studying the properties of space and its relationship with time.
Analyzing the principles of the Big Bang Theory and its implications.
Investigating the properties of the Higgs boson and its impact on particle physics.
Studying the properties of string theory and its implications.
Analyzing the principles of chaos theory and its applications in physics.

Physics Research Topics for UnderGraduate

Investigating the effects of temperature on the conductivity of different materials.
Studying the behavior of light in different mediums.
Analyzing the properties of superconductors and their potential applications.
Examining the principles of thermodynamics and their practical applications.
Investigating the behavior of sound waves in different environments.
Studying the characteristics of magnetic fields and their applications.
Analyzing the principles of optics and their role in modern technology.
Examining the principles of quantum mechanics and their implications.
Investigating the properties of semiconductors and their use in electronics.
Studying the properties of gases and their behavior under different conditions.
Analyzing the principles of nuclear physics and their practical applications.
Examining the properties of waves and their applications in communication.
Investigating the principles of relativity and their implications for the nature of space and time.
Studying the behavior of particles in different environments, including accelerators and colliders.
Analyzing the principles of chaos theory and their implications for complex systems.
Examining the principles of fluid mechanics and their applications in engineering and science.
Investigating the principles of solid-state physics and their applications in materials science.
Studying the properties of electromagnetic waves and their use in modern technology.
Analyzing the principles of gravitation and their role in the structure of the universe.
Examining the principles of quantum field theory and their implications for the nature of particles and fields.
Investigating the properties of black holes and their role in astrophysics.
Studying the principles of string theory and their implications for the nature of matter and energy.
Analyzing the properties of dark matter and its role in cosmology.
Examining the principles of condensed matter physics and their applications in materials science.
Investigating the principles of statistical mechanics and their implications for the behavior of large systems.
Studying the properties of plasma and its applications in fusion energy research.
Analyzing the principles of general relativity and their implications for the nature of space-time.
Examining the principles of quantum computing and its potential applications.
Investigating the principles of high energy physics and their role in understanding the fundamental laws of nature.
Studying the principles of astrobiology and their implications for the search for life beyond Earth.

Physics Research Topics for Masters

Investigating the principles and applications of quantum cryptography.
Analyzing the behavior of Bose-Einstein condensates and their potential applications.
Studying the principles of photonics and their role in modern technology.
Examining the properties of topological materials and their potential applications.
Investigating the principles and applications of graphene and other 2D materials.
Studying the principles of quantum entanglement and their implications for information processing.
Analyzing the principles of quantum field theory and their implications for particle physics.
Examining the properties of quantum dots and their use in nanotechnology.
Investigating the principles of quantum sensing and their potential applications.
Studying the behavior of quantum many-body systems and their potential applications.
Analyzing the principles of cosmology and their implications for the early universe.
Examining the principles of dark energy and dark matter and their role in cosmology.
Investigating the properties of gravitational waves and their detection.
Studying the principles of quantum computing and their potential applications in solving complex problems.
Analyzing the properties of topological insulators and their potential applications in quantum computing and electronics.
Examining the principles of quantum simulations and their potential applications in studying complex systems.
Investigating the principles of quantum error correction and their implications for quantum computing.
Studying the behavior of quarks and gluons in high energy collisions.
Analyzing the principles of quantum phase transitions and their implications for condensed matter physics.
Examining the principles of quantum annealing and their potential applications in optimization problems.
Investigating the properties of spintronics and their potential applications in electronics.
Studying the behavior of non-linear systems and their applications in physics and engineering.
Analyzing the principles of quantum metrology and their potential applications in precision measurement.
Examining the principles of quantum teleportation and their implications for information processing.
Investigating the properties of topological superconductors and their potential applications.
Studying the principles of quantum chaos and their implications for complex systems.
Analyzing the properties of magnetars and their role in astrophysics.
Examining the principles of quantum thermodynamics and their implications for the behavior of small systems.
Investigating the principles of quantum gravity and their implications for the structure of the universe.
Studying the behavior of strongly correlated systems and their applications in condensed matter physics.

Physics Research Topics for PhD

Quantum computing: theory and applications.
Topological phases of matter and their applications in quantum information science.
Quantum field theory and its applications to high-energy physics.
Experimental investigations of the Higgs boson and other particles in the Standard Model.
Theoretical and experimental study of dark matter and dark energy.
Applications of quantum optics in quantum information science and quantum computing.
Nanophotonics and nanomaterials for quantum technologies.
Development of advanced laser sources for fundamental physics and engineering applications.
Study of exotic states of matter and their properties using high energy physics techniques.
Quantum information processing and communication using optical fibers and integrated waveguides.
Advanced computational methods for modeling complex systems in physics.
Development of novel materials with unique properties for energy applications.
Magnetic and spintronic materials and their applications in computing and data storage.
Quantum simulations and quantum annealing for solving complex optimization problems.
Gravitational waves and their detection using interferometry techniques.
Study of quantum coherence and entanglement in complex quantum systems.
Development of novel imaging techniques for medical and biological applications.
Nanoelectronics and quantum electronics for computing and communication.
High-temperature superconductivity and its applications in power generation and storage.
Quantum mechanics and its applications in condensed matter physics.
Development of new methods for detecting and analyzing subatomic particles.
Atomic, molecular, and optical physics for precision measurements and quantum technologies.
Neutrino physics and its role in astrophysics and cosmology.
Quantum information theory and its applications in cryptography and secure communication.
Study of topological defects and their role in phase transitions and cosmology.
Experimental study of strong and weak interactions in nuclear physics.
Study of the properties of ultra-cold atomic gases and Bose-Einstein condensates.
Theoretical and experimental study of non-equilibrium quantum systems and their dynamics.
Development of new methods for ultrafast spectroscopy and imaging.
Study of the properties of materials under extreme conditions of pressure and temperature.

Random Physics Research Topics

Quantum entanglement and its applications
Gravitational waves and their detection
Dark matter and dark energy
High-energy particle collisions and their outcomes
Atomic and molecular physics
Theoretical and experimental study of superconductivity
Plasma physics and its applications
Neutrino oscillations and their detection
Quantum computing and information
The physics of black holes and their properties
Study of subatomic particles like quarks and gluons
Investigation of the nature of time and space
Topological phases in condensed matter systems
Magnetic fields and their applications
Nanotechnology and its impact on physics research
Theory and observation of cosmic microwave background radiation
Investigation of the origin and evolution of the universe
Study of high-temperature superconductivity
Quantum field theory and its applications
Study of the properties of superfluids
The physics of plasmonics and its applications
Experimental and theoretical study of semiconductor materials
Investigation of the quantum Hall effect
The physics of superstring theory and its applications
Theoretical study of the nature of dark matter
Study of quantum chaos and its applications
Investigation of the Casimir effect
The physics of spintronics and its applications
Study of the properties of topological insulators
Investigation of the nature of the Higgs boson
The physics of quantum dots and its applications
Study of quantum many-body systems
Investigation of the nature of the strong force
Theoretical and experimental study of photonics
Study of topological defects in condensed matter systems
Investigation of the nature of the weak force
The physics of plasmas in space
Study of the properties of graphene
Investigation of the nature of antimatter
The physics of optical trapping and manipulation
Study of the properties of Bose-Einstein condensates
Investigation of the nature of the neutrino
The physics of quantum thermodynamics
Study of the properties of quantum dots
Investigation of the nature of dark energy
The physics of magnetic confinement fusion
Study of the properties of topological quantum field theories
Investigation of the nature of gravitational lensing
The physics of laser cooling and trapping
Study of the properties of quantum Hall states.
The effects of dark energy on the expansion of the universe
Quantum entanglement and its applications in cryptography
The study of black holes and their event horizons
The potential existence of parallel universes
The relationship between dark matter and the formation of galaxies
The impact of solar flares on the Earth’s magnetic field
The effects of cosmic rays on human biology
The development of quantum computing technology
The properties of superconductors at high temperatures
The search for a theory of everything
The study of gravitational waves and their detection
The behavior of particles in extreme environments such as neutron stars
The relationship between relativity and quantum mechanics
The development of new materials for solar cells
The study of the early universe and cosmic microwave background radiation
The physics of the human voice and speech production
The behavior of matter in extreme conditions such as high pressure and temperature
The properties of dark matter and its interactions with ordinary matter
The potential for harnessing nuclear fusion as a clean energy source
The study of high-energy particle collisions and the discovery of new particles
The physics of biological systems such as the brain and DNA
The behavior of fluids in microgravity environments
The properties of graphene and its potential applications in electronics
The physics of natural disasters such as earthquakes and tsunamis
The development of new technologies for space exploration and travel
The study of atmospheric physics and climate change
The physics of sound and musical instruments
The behavior of electrons in quantum dots
The properties of superfluids and Bose-Einstein condensates
The physics of animal locomotion and movement
The development of new imaging techniques for medical applications
The physics of renewable energy sources such as wind and hydroelectric power
The properties of quantum materials and their potential for quantum computing
The physics of sports and athletic performance
The study of magnetism and magnetic materials
The physics of earthquakes and the prediction of seismic activity
The behavior of plasma in fusion reactors
The properties of exotic states of matter such as quark-gluon plasma
The development of new technologies for energy storage
The physics of fluids in porous media
The properties of quantum dots and their potential for new technologies
The study of materials under extreme conditions such as extreme temperatures and pressures
The physics of the human body and medical imaging
The development of new materials for energy conversion and storage
The study of cosmic rays and their effects on the atmosphere and human health
The physics of friction and wear in materials
The properties of topological materials and their potential for new technologies
The physics of ocean waves and tides
The behavior of particles in magnetic fields
The properties of complex networks and their application in various fields

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A List of 240 Physics Topics & Questions to Research

Plates break when you drop them. Glasses help you see better. Have you ever wondered why?

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Physics has the answer. It studies the observable as well as invisible aspects of nature. An essential part of this is examining the structure and interactions of matter.

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🔝 Top 10 Physics Research Topics

✅ branches of physics.

⭐ Top 10 Physics Topics
⚙️ Mechanics
🌡️ Thermodynamics
⚡ Electromagnetism
🔊 Sounds & Waves
☢️ Modern Physics
🔋 Physics Project Topics
🔭 Astrophysics
🌎 Physical Geography
🤔 Theoretical Physics
⚛️ Quantum Physics

🔍 References

Modern vs. classical physics
Gravity method in geophysics
Why can’t the multiverse be real?
Nuclear physics vs. quantum physics
Photonics’ relationship to other fields
Is electromagnetism the strongest force?
What would extra dimensions look like?
The importance of kinematics in real life
Is string theory a generalization of quantum field theory?
The difference between liquid pressure and air pressure

Now: before writing about physics you should know about its main branches. These are classical and modern . Let’s take a closer look:

Mechanics , which is concerned with motion. Two of its essential aspects are kinematics and dynamics.
Optics helps us understand the properties of light.
Another branch investigates waves and sound . It studies the way they travel and how they are produced.
Thermodynamics deals with heat and motion. One of its key concepts is entropy.
Electromagnetism studies the interactions between charged particles. It also deals with the forces and fields that surround them.
Finally, physical geographers observe our Earth’s physical features. These include environmental processes and patterns.
Atomic physics , which examines the structure and behavior of atoms.
Nuclear physics investigates the nucleus of atoms. This branch often deals with radioactivity.
Scientists working in quantum physics concentrate on the erratic behavior of waves and particles.
Relativity can be general and special. Special relativity deals with time and motion. General relativity describes gravity as an alteration of spacetime caused by massive objects.
Cosmology and astrophysics explore the properties of celestial bodies. Cosmologists strive to comprehend the universe on a larger scale.
Mesoscopic physics covers the scale between macroscopic and microscopic.

You can talk about any of these branches in your essay. Keep in mind that this division is a basic outline. Strictly speaking, everything that happens around you is physics! Now, we’re all set to move on to our physics paper topics.

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⭐ Top 10 Physics Topics 2024

Biophysics vs. biochemistry
The future of nano-physics
The use of perturbation theory
Possible cause of baryogenesis
Solid-state vs. condensed matter physics
Why is the quark model introduced?
The importance of plasma in physics
Statistical mechanics vs. statistical physics
Ways to calculate electronic structure
Difference between matter and dark matter

🧲 Classical Physics Topics to Write About

Classical physics deals with energy, force, and motion. You encounter this kind of physics in everyday life. Below, we’ve compiled a list with compelling prompts you’ll recognize from your physics class:

⚙️ Mechanics Essay Topics

What does Newton’s laws of motion state?
How do ships stay afloat?
Equipartition: for what systems does it not hold?
What does Bernoulli’s principle state about fluids?
Surface tension: what causes it?
How does buoyancy work?
An overview of the molecular origins of viscosity.
The equipartition theorem: how does it connect a system’s temperature to its energies?
The benefits of the continuum assumption.
Contrast the different types of forces.
Explain the term “momentum.”
Kinematics: describing the relationships of objects in constrained motion.
What causes objects to oscillate?

🌡️ Thermodynamics Paper Topics

Thermodynamics as a kinetic theory of matter.
What is entropy?
Describe the three types of thermodynamic processes.
The Carnot heat engine as part of a thermodynamic cycle.

Perpetual motion: is it possible or not?
Investigate fire in terms of chemistry and thermodynamics.

⚡ Electromagnetism Topics to Research

Examine the connection between electric potential and electric field.
What makes an excellent conduit?
How does a dielectric impact a capacitor?
Contrast current, resistance, and power.
How do magnetic fields relate to electricity?
Explain inductance. What causes it?
How do induction stoves work?

🔊 Essay Topics on Sounds & Waves

Sound waves: how do they travel?
Describe the two types of mechanical waves.
What are electromagnetic waves used for?
The difference between interference and diffraction.
Music and vibrations: the properties of sound.

👓 Optics Topics to Write About

How does reflection work?
What happens when an object absorbs light?
Why does light break into a rainbow?
Lasers: what do we use them for?
What causes Aurora Borealis?
Photography: what happens when you change the aperture?
Explain what influences the colors of sunsets.
Fata Morgana mirages: where do they originate from?
What is the Novaya Zemlya effect?

☢️ Modern Physics Topics for a Paper

The world of modern physics shifts away from its more tangible origins. It deals with atoms and even smaller particles. Nuclear, atomic, and quantum physics belong to this category. One of the central problems of modern physics is redefining the concept of gravity.

Relativity: a discovery that turned our understanding of physics upside down.
An overview of 20th century physics.
The ultraviolet catastrophe and how it was solved.
What happens to the energy entering an ideal blackbody?
The photoelectric effect: creating current with light.
Why did the classical lightwave model become outdated?
How do night vision devices work?
The production of x-rays.
Explain why the charge of electrons is quantized.
How does the kinetic energy of an electron relate to the light’s frequency and intensity?
Describe the photon model of the Compton Scattering.
How do you identify an element using its line spectra?
Cold Fusion: how likely is it?
Explain the Pauli Exclusion Principle.
Electron shells and atomic orbitals: properties of electrons.
What causes peaks in the x-ray spectrum?
How do you calculate radioactive decay?
Carbon dating: how accurate is it?
The discovery of radioactivity.
What holds electronic nuclei together?
Nuclear Fusion: will it ever be possible?
Describe the types of elemental transmutation.
Applications of nuclear fission.
Virtual particles: how do they come into existence?

Nucleosynthesis: creating atomic nuclei.
How do you dope a semiconductor using ion implantation?
What are the magic numbers?
Superheavy primordial elements: the history of unbihexium.
Predictions surrounding the island of stability.
How does a computer tomography work?

🔋 Physics Project Topics for a Science Fair

What’s the most fun part of every natural science? If you said “experiments,” you guessed it! Everybody can enjoy creating rainbows or exploring the effects of magnets. Your next physics project will be as fascinating as you want it to be with these exciting ideas!

Build a kaleidoscope and learn how it works.
Investigate the centripetal force with the help of gelatin and marbles.
Make a potato battery.
Construct an elevator system.
Prove Newton’s laws of motion by placing objects of different weights in a moving elevator.
Learn how a telescope works. Then build one from scratch.
Levitate small objects using ultrasound.
Measure how fast a body in free fall accelerates.
Find out what causes a capacitor to charge and discharge over time.
Measure how light intensity changes through several polarizing filters.
Observe how sound waves change under altered atmospheric conditions.
Find out how a superheated object is affected by its container.
Determine the mathematics behind a piece of classical music.
Replicate an oil spill and search for the best way to clean it up.
What makes a circular toy easy to spin? Experiment by spinning hula hoops of different sizes.
Make DNA visible. What happens if you use different sources of plant-based DNA?
Charge your phone with a handmade solar cell.
Find out what properties an object needs to stay afloat.
Create music by rubbing your finger against the rim of a glass. Experiment with several glasses filled with different amounts of water.
Compare the free-fall speed of a Lego figure using various parachutes.
Experiment with BEC to understand quantum mechanics.
Make a windmill and describe how it works.
Build an automatic light circuit using a laser.
How do concave and convex mirrors affect your reflection?
Investigate how pressure and temperature influence the air volume.
Determine the conductivity of different fluids.
Learn about the evolution of the universe by measuring electromagnetic radiation.
Capture charged particles in an ion trap.
Build a rocket car using a balloon.
Experiment with pendulums and double pendulums. How do they work?

🔭 Astrophysics Topics for a Research Paper

Astrophysicists, astronomers, and cosmologists observe what happens in space. Astronomy examines celestial bodies, while astrophysics describes their mechanics. At the same time, cosmology attempts to comprehend the universe as a whole.

Explain when a celestial body is called a planet.
Dark energy and dark matter: how do they affect the expansion of the universe?
The cosmic microwave background: investigating the birth of the universe.
What are the possible explanations for the expansion of the universe?
Evidence for the existence of dark matter.
The discovery of gravitational waves: consequences and implications.
Explore the history of LIGO.
How did scientists observe a black hole?
The origins of light.
Compare the types of stars.
Radioactivity in space: what is it made of?
What do we know about stellar evolution?
Rotations of the Milky Way.
Write an overview of recent developments in astrophysics.
Investigate the origin of moons.
How do we choose names for constellations?
What are black holes?
How does radiative transfer work in space?
What does our solar system consist of?
Describe the properties of a star vs. a moon.

What makes binary stars special?
Gamma-ray bursts: how much energy do they produce?
What causes supernovae?
Compare the types of galaxies.
Neutron stars and pulsars: how do they differ?
The connection between stars and their colors.
What are quasars?
Curved space: is there enough evidence to support the theory?
What produces x-rays in space?
Exoplanets: what do we know about them?

🌎 Physical Geography Topics to Write About

Physical geographers explore the beauty of our Earth. Their physical knowledge helps them explain how nature works. What causes climate change? Where do our seasons come from? What happens in the ocean? These are the questions physical geographers seek to answer.

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What creates rainbows?
How do glaciers form?
The geographical properties of capes.
What causes landslides?
An overview of the types of erosion.
What makes Oceania’s flora unique?
Reefs: why are they important?
Why is there a desert in the middle of Siberia?
The geography of the Namibian desert.
Explain the water cycle.
How do you measure the length of a river?
The Gulf Stream and its influence on the European climate.
Why is the sky blue?
What creates waves?
How do marshes form?
Investigate the causes of riptides.
The Three Gorges Dam: how was it built?
Explain the phenomenon of Green Sahara.
The consequences of freshwater pollution.
What are the properties of coastal plains?
Why is the Atacama Desert the driest place on Earth?
How does a high altitude affect vegetation?
Atmospheric changes over the past 100 years.
Predicting earthquakes: a comparison of different methods.
What causes avalanches?
Seasons: where do they come from?
The Baltic and the Northern Seas meeting phenomenon.
The geographical properties of the Altai Mountains.
How do the steppes form?
Why are some water bodies saltier than others?

🤔 Theoretical Physics Topics to Research

Math fans, this section is for you. Theoretical physics is all about equations. Research in this area goes into the development of mathematical and computer models. Plus, theoretical physicists try to construct theories for phenomena that currently can’t be explained experimentally.

What does the Feynman diagram describe?
How is QFT used to model quasiparticles?
String theory: is it a theory of everything?
The paradoxical effects of time travel.
Monstrous moonshine: how does it connect to string theory?
Mirror symmetry and Calabi-Yau manifolds: how are they used in physics?
Understanding the relationship between gravity and BF theories.
Compare the types of Gauge theories.

Applications of TQFT in condensed matter physics.
Examine the properties of fields with arbitrary spin.
How do quarks and gluons interact with each other?
What predictions does quantum field theory make for curved spacetime?
How do technicolor theories explain electroweak gauge symmetry breaking?
Quantum gravity: a comparison of approaches.
How does LQG address the structure of space?
An introduction into the motivation behind the eigenstate thermalization hypothesis.
What does the M-theory state?
What does the Ising model say about ferromagnetism?
Compare the thermodynamic Debye model with the Einstein model.
How does the kinetic theory describe the macroscopic properties of gases?
Understanding the behavior of waves and particles: scattering theory.
What was the luminiferous aether assumption needed for?
The Standard Model of particles: why is it not a full theory of fundamental interactions?
Investigate supersymmetry.
Physical cosmology: measuring the universe.
Describe the black hole thermodynamics.
Pancomputationalism: what is it about?
Skepticism concerning the E8 theory.
Explain the conservation of angular momentum.
What does the dynamo theory say about celestial bodies?

⚛️ Quantum Physics Topics for Essays & Papers

First and foremost, quantum physics is very confusing. In quantum physics, an object is not just in a specific place. It merely has the probability to be in one place or another. Light travels in particles, and matter can be a wave. Throw physics as you know it overboard. In this world, you can never be sure what and where things really are.

How did the Schrödinger Equation advance quantum physics?
Describe the six types of quarks.
Contrast the four quantum numbers.
What kinds of elementary particles exist?
Probability density: finding electrons.
How do you split an atom using quantum mechanics?
When is an energy level degenerate?
Quantum entanglement: how does it affect particles?
The double-slit experiment: what does it prove?
What causes a wave function to collapse?
Explore the history of quantum mechanics.
What are quasiparticles?
The Higgs mechanism: explaining the mass of bosons.
Quantum mechanical implications of the EPR paradox.
What causes explicit vs. spontaneous symmetry breaking?
Discuss the importance of the observer.
What makes gravity a complicated subject?
Can quantum mechanical theories accurately depict the real world?
Describe the four types of exchange particles.
What are the major problems surrounding quantum physics?
What does Bell’s theorem prove?
How do bubble chambers work?
Understanding quantum mechanics: the Copenhagen interpretation.
Will teleportation ever be possible on a large scale?
The applications of Heisenberg’s uncertainty principle.
Wave packets: how do you localize them?
How do you process quantum information?
What does the Fourier transform do?
The importance of Planck’s constant.
Matter as waves: the Heisenberg-Schrödinger atom model.

We hope you’ve found a great topic for your best physics paper. Good luck with your assignment!

Physics Theses, Dissertations, and Masters Projects

Theses/dissertations from 2023 2023.

Ab Initio Computations Of Structural Properties In Solids By Auxiliary Field Quantum Monte Carlo , Siyuan Chen

Constraining Of The Minerνa Medium Energy Neutrino Flux Using Neutrino-Electron Scattering , Luis Zazueta

Experimental Studies Of Neutral Particles And The Isotope Effect In The Edge Of Tokamak Plasmas , Ryan Chaban

From The Hubbard Model To Coulomb Interactions: Quantum Monte Carlo Computations In Strongly Correlated Systems , Zhi-Yu Xiao

Theses/Dissertations from 2022 2022

Broadband Infrared Microspectroscopy and Nanospectroscopy of Local Material Properties: Experiment and Modeling , Patrick McArdle

Edge Fueling And Neutral Density Studies Of The Alcator C-Mod Tokamak Using The Solps-Iter Code , Richard M. Reksoatmodjo

Electronic Transport In Topological Superconducting Heterostructures , Joseph Jude Cuozzo

Inclusive and Inelastic Scattering in Neutrino-Nucleus Interactions , Amy Filkins

Investigation Of Stripes, Spin Density Waves And Superconductivity In The Ground State Of The Two-Dimensional Hubbard Model , Hao Xu

Partial Wave Analysis Of Strange Mesons Decaying To K + Π − Π + In The Reaction Γp → K + Π + Π − Λ(1520) And The Commissioning Of The Gluex Dirc Detector , Andrew Hurley

Partial Wave Analysis of the ωπ− Final State Photoproduced at GlueX , Amy Schertz

Quantum Sensing For Low-Light Imaging , Savannah Cuozzo

Radiative Width of K*(892) from Lattice Quantum Chromodynamics , Archana Radhakrishnan

Theses/Dissertations from 2021 2021

AC & DC Zeeman Interferometric Sensing With Ultracold Trapped Atoms On A Chip , Shuangli Du

Calculation Of Gluon Pdf In The Nucleon Using Pseudo-Pdf Formalism With Wilson Flow Technique In LQCD , Md Tanjib Atique Khan

Dihadron Beam Spin Asymmetries On An Unpolarized Hydrogen Target With Clas12 , Timothy Barton Hayward

Excited J-- Resonances In Meson-Meson Scattering From Lattice Qcd , Christopher Johnson

Forward & Off-Forward Parton Distributions From Lattice Qcd , Colin Paul Egerer

Light-Matter Interactions In Quasi-Two-Dimensional Geometries , David James Lahneman

Proton Spin Structure from Simultaneous Monte Carlo Global QCD Analysis , Yiyu Zhou

Radiofrequency Ac Zeeman Trapping For Neutral Atoms , Andrew Peter Rotunno

Theses/Dissertations from 2020 2020

A First-Principles Study of the Nature of the Insulating Gap in VO2 , Christopher Hendriks

Competing And Cooperating Orders In The Three-Band Hubbard Model: A Comprehensive Quantum Monte Carlo And Generalized Hartree-Fock Study , Adam Chiciak

Development Of Quantum Information Tools Based On Multi-Photon Raman Processes In Rb Vapor , Nikunjkumar Prajapati

Experiments And Theory On Dynamical Hamiltononian Monodromy , Matthew Perry Nerem

Growth Engineering And Characterization Of Vanadium Dioxide Films For Ultraviolet Detection , Jason Andrew Creeden

Insulator To Metal Transition Dynamics Of Vanadium Dioxide Thin Films , Scott Madaras

Quantitative Analysis Of EKG And Blood Pressure Waveforms , Denise Erin McKaig

Study Of Scalar Extensions For Physics Beyond The Standard Model , Marco Antonio Merchand Medina

Theses/Dissertations from 2019 2019

Beyond the Standard Model: Flavor Symmetry, Nonperturbative Unification, Quantum Gravity, and Dark Matter , Shikha Chaurasia

Electronic Properties of Two-Dimensional Van Der Waals Systems , Yohanes Satrio Gani

Extraction and Parametrization of Isobaric Trinucleon Elastic Cross Sections and Form Factors , Scott Kevin Barcus

Interfacial Forces of 2D Materials at the Oil–Water Interface , William Winsor Dickinson

Scattering a Bose-Einstein Condensate Off a Modulated Barrier , Andrew James Pyle

Topics in Proton Structure: BSM Answers to its Radius Puzzle and Lattice Subtleties within its Momentum Distribution , Michael Chaim Freid

Theses/Dissertations from 2018 2018

A Measurement of Nuclear Effects in Deep Inelastic Scattering in Neutrino-Nucleus Interactions , Anne Norrick

Applications of Lattice Qcd to Hadronic Cp Violation , David Brantley

Charge Dynamics in the Metallic and Superconducting States of the Electron-Doped 122-Type Iron Arsenides , Zhen Xing

Dynamics of Systems With Hamiltonian Monodromy , Daniel Salmon

Exotic Phases in Attractive Fermions: Charge Order, Pairing, and Topological Signatures , Peter Rosenberg

Extensions of the Standard Model Higgs Sector , Richard Keith Thrasher

First Measurements of the Parity-Violating and Beam-Normal Single-Spin Asymmetries in Elastic Electron-Aluminum Scattering , Kurtis David Bartlett

Lattice Qcd for Neutrinoless Double Beta Decay: Short Range Operator Contributions , Henry Jose Monge Camacho

Probe of Electroweak Interference Effects in Non-Resonant Inelastic Electron-Proton Scattering , James Franklyn Dowd

Proton Spin Structure from Monte Carlo Global Qcd Analyses , Jacob Ethier

Searching for A Dark Photon in the Hps Experiment , Sebouh Jacob Paul

Theses/Dissertations from 2017 2017

A global normal form for two-dimensional mode conversion , David Gregory Johnston

Computational Methods of Lattice Boltzmann Mhd , Christopher Robert Flint

Computational Studies of Strongly Correlated Quantum Matter , Hao Shi

Determination of the Kinematics of the Qweak Experiment and Investigation of an Atomic Hydrogen Møller Polarimeter , Valerie Marie Gray

Disconnected Diagrams in Lattice Qcd , Arjun Singh Gambhir

Formulating Schwinger-Dyson Equations for Qed Propagators in Minkowski Space , Shaoyang Jia

Highly-Correlated Electron Behavior in Niobium and Niobium Compound Thin Films , Melissa R. Beebe

Infrared Spectroscopy and Nano-Imaging of La0.67Sr0.33Mno3 Films , Peng Xu

Investigation of Local Structures in Cation-Ordered Microwave Dielectric a Solid-State Nmr and First Principle Calculation Study , Rony Gustam Kalfarisi

Measurement of the Elastic Ep Cross Section at Q2 = 0.66, 1.10, 1.51 and 1.65 Gev2 , YANG WANG

Modeling The Gross-Pitaevskii Equation using The Quantum Lattice Gas Method , Armen M. Oganesov

Optical Control of Multi-Photon Coherent Interactions in Rubidium Atoms , Gleb Vladimirovich Romanov

Plasmonic Approaches and Photoemission: Ag-Based Photocathodes , Zhaozhu Li

Quantum and Classical Manifestation of Hamiltonian Monodromy , Chen Chen

Shining Light on The Phase Transitions of Vanadium Dioxide , Tyler J. Huffman

Superconducting Thin Films for The Enhancement of Superconducting Radio Frequency Accelerator Cavities , Matthew Burton

Theses/Dissertations from 2016 2016

Ac Zeeman Force with Ultracold Atoms , Charles Fancher

A Measurement of the Parity-Violating Asymmetry in Aluminum and its Contribution to A Measurement of the Proton's Weak Charge , Joshua Allen Magee

An improved measurement of the Muon Neutrino charged current Quasi-Elastic cross-section on Hydrocarbon at Minerva , Dun Zhang

Applications of High Energy Theory to Superconductivity and Cosmic Inflation , Zhen Wang

A Precision Measurement of the Weak Charge of Proton at Low Q^2: Kinematics and Tracking , Siyuan Yang

Compton Scattering Polarimetry for The Determination of the Proton’S Weak Charge Through Measurements of the Parity-Violating Asymmetry of 1H(E,e')P , Juan Carlos Cornejo

Disorder Effects in Dirac Heterostructures , Martin Alexander Rodriguez-Vega

Electron Neutrino Appearance in the Nova Experiment , Ji Liu

Experimental Apparatus for Quantum Pumping with a Bose-Einstein Condensate. , Megan K. Ivory

Investigating Proton Spin Structure: A Measurement of G_2^p at Low Q^2 , Melissa Ann Cummings

Neutrino Flux Prediction for The Numi Beamline , Leonidas Aliaga Soplin

Quantitative Analysis of Periodic Breathing and Very Long Apnea in Preterm Infants. , Mary A. Mohr

Resolution Limits of Time-of-Flight Mass Spectrometry with Pulsed Source , Guangzhi Qu

Solving Problems of the Standard Model through Scale Invariance, Dark Matter, Inflation and Flavor Symmetry , Raymundo Alberto Ramos

Study of Spatial Structure of Squeezed Vacuum Field , Mi Zhang

Study of Variations of the Dynamics of the Metal-Insulator Transition of Thin Films of Vanadium Dioxide with An Ultra-Fast Laser , Elizabeth Lee Radue

Thin Film Approaches to The Srf Cavity Problem: Fabrication and Characterization of Superconducting Thin Films , Douglas Beringer

Turbulent Particle Transport in H-Mode Plasmas on Diii-D , Xin Wang

Theses/Dissertations from 2015 2015

Ballistic atom pumps , Tommy Byrd

Determination of the Proton's Weak Charge via Parity Violating e-p Scattering. , Joshua Russell Hoskins

Electronic properties of chiral two-dimensional materials , Christopher Lawrence Charles Triola

Heavy flavor interactions and spectroscopy from lattice quantum chromodynamics , Zachary S. Brown

Some properties of meson excited states from lattice QCD , Ekaterina V. Mastropas

Sterile Neutrino Search with MINOS. , Alena V. Devan

Ultracold rubidium and potassium system for atom chip-based microwave and RF potentials , Austin R. Ziltz

Theses/Dissertations from 2014 2014

Enhancement of MS Signal Processing for Improved Cancer Biomarker Discovery , Qian Si

Whispering-gallery mode resonators for nonlinear and quantum optical applications , Matthew Thomas Simons

Theses/Dissertations from 2013 2013

Applications of Holographic Dualities , Dylan Judd Albrecht

A search for a new gauge boson , Eric Lyle Jensen

Experimental Generation and Manipulation of Quantum Squeezed Vacuum via Polarization Self-Rotation in Rb Vapor , Travis Scott Horrom

Low Energy Tests of the Standard Model , Benjamin Carl Rislow

Magnetic Order and Dimensional Crossover in Optical Lattices with Repulsive Interaction , Jie Xu

Multi-meson systems from Lattice Quantum Chromodynamics , Zhifeng Shi

Theses/Dissertations from 2012 2012

Dark matter in the heavens and at colliders: Models and constraints , Reinard Primulando

Measurement of Single and Double Spin Asymmetries in p(e, e' pi(+/-,0))X Semi-Inclusive Deep-Inelastic Scattering , Sucheta Shrikant Jawalkar

NMR study of paramagnetic nano-checkerboard superlattices , Christopher andrew Maher

Parity-violating asymmetry in the nucleon to delta transition: A Study of Inelastic Electron Scattering in the G0 Experiment , Carissa Lee Capuano

Studies of polarized and unpolarized helium -3 in the presence of alkali vapor , Kelly Anita Kluttz

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121+ Scientific Research Topics for High School Students

High school is a time of exploration, and for budding scientists, it’s the perfect opportunity to dive into the exciting world of scientific research. Whether you’re passionate about biology, chemistry, physics, or the social sciences, there’s a wealth of fascinating topics waiting to be explored.

In this blog, we’ve compiled over engaging scientific research topics for high school students. These topics not only ignite your curiosity but also align with your academic journey. From unraveling the mysteries of genetics to exploring the cosmos, we’ve got you covered. So, let’s embark on this thrilling adventure of discovery and learning together!

What is a Scientific Research Topic?

Table of Contents

A scientific research topic is a specific subject or question that scientists or researchers investigate through a structured and systematic approach. These topics can cover a wide range of fields, from biology and chemistry to physics and social sciences. The goal of selecting a research topic is to address a problem, explore a hypothesis, or contribute new insights to an existing body of knowledge.

Why Engage in Scientific Research as a High School Student?

High school is the perfect time to start exploring scientific research because it:

Fosters curiosity and a love for learning.
Enhances problem-solving and critical thinking skills.
Offers a taste of what a future career in science might entail.
Provides an edge in college applications.

How to Choose the Right Scientific Research Topics for High School Students?

Selecting a research topic can be challenging, but it’s essential to choose something that genuinely interests you. When choosing a scientific research topic, it’s essential to consider the following factors:

Interest: Select a topic that genuinely interests you. Your enthusiasm will drive your research forward.
Relevance: Ensure that your topic is relevant to the field you’re studying or the scientific discipline you’re interested in.
Feasibility: Assess whether you have access to the necessary resources and equipment to conduct research on your chosen topic.
Ethical Considerations: Make sure your research is conducted ethically and follows all relevant guidelines and regulations.

Interesting Scientific Research Topics for High School Students

Now, let’s dive into the exciting world of scientific research topics for high school students in different categories:

Biology Research Topics

Let’s explore the scientific research topics for students in biology:

1. The impact of different types of diets on human health.

2. Investigating the effects of climate change on local ecosystems.

3. Studying the genetics of a specific inherited disease.

4. Exploring the biodiversity of a local habitat.

5. Investigating the role of microorganisms in soil health.

6. Analyzing the effects of pollution on aquatic life.

7. Studying the behavior of a specific animal species.

8. Investigating the impact of a new drug on cell growth.

9. Exploring the relationship between exercise and heart health.

10. Studying the effects of various fertilizers on plant growth.

11. Investigating the genetics of taste perception.

12. Exploring the impact of environmental factors on plant adaptation.

Chemistry Research Topics

Here are some scientific research topics for high school students in chemistry:

1. Investigating the properties of different types of polymers.

2. Studying the effects of pH on chemical reactions.

3. Analyzing the composition of a local water source.

4. Exploring the chemistry of food preservation methods.

5. Investigating the synthesis of a specific chemical compound.

6. Studying the effects of temperature on reaction rates.

7. Analyzing the chemical components of household products.

8. Investigating the properties of nanomaterials.

9. Exploring the chemistry of natural dyes.

10. Studying the chemical reactions involved in baking.

11. Investigating the chemistry of fireworks.

12. Analyzing the composition of air pollutants in your area.

Physics Research Topics

Let’s dive into the physics research topics for high school students:

1. Investigating the laws of motion using simple experiments.

2. Studying the behavior of light using prisms and lenses.

3. Analyzing the effects of different materials on magnetic fields.

4. Exploring the properties of waves and sound.

5. Investigating the relationship between temperature and electrical conductivity.

6. Studying the principles of electromagnetism.

7. Analyzing the motion of objects in a vacuum.

8. Investigating the behavior of pendulums.

9. Exploring the properties of different types of mirrors.

10. Studying the physics of roller coasters.

11. Investigating the properties of superconductors.

12. Analyzing the behavior of particles in nuclear reactions.

Environmental Science Research Topics

Discover some scientific research topics for high school students in environmental:

1. Studying the impact of deforestation on local climate.

2. Investigating the effects of pollution on aquatic ecosystems.

3. Analyzing the biodiversity of a local wetland area.

4. Exploring the use of renewable energy sources in your community.

5. Investigating the impact of plastic waste on marine life.

6. Studying the effects of urbanization on local wildlife.

7. Analyzing the water quality in a nearby river.

8. Investigating the effectiveness of different recycling methods.

9. Exploring the impact of climate change on bird migration patterns.

10. Studying the use of sustainable agriculture practices.

11. Investigating the effects of air pollution on respiratory health.

12. Analyzing the benefits of green roofs in urban areas.

Social Science Research Topics

Here are some social science research topics for high school students:

1. Investigating the impact of social media on mental health.

2. Studying the effects of peer pressure on academic performance.

3. Analyzing the relationship between family dynamics and child development.

4. Exploring the influence of music on mood and behavior.

5. Investigating the effects of bullying on adolescent well-being.

6. Studying the role of gender stereotypes in career choices.

7. Analyzing the impact of video games on cognitive skills.

8. Investigate the factors influencing voter turnout in your community.

9. Exploring the effects of income inequality on social mobility.

10. Studying the relationship between parental involvement and student success.

11. Investigating the influence of advertising on consumer behavior.

12. Analyzing the impact of cultural diversity on community cohesion.

Astronomy Research Topics

Let’s explore the scientific research topics for high school students in astronomy:

1. Studying the phases of the moon and their impact on tides.

2. Investigating the properties of asteroids and comets.

3. Analyzing the life cycle of stars.

4. Exploring the potential for life on other planets.

5. Investigating the effects of light pollution on stargazing.

6. Studying the orbits of planets in our solar system.

7 Analyzing the properties of black holes.

8. Investigating the formation of galaxies.

9. Exploring the search for extraterrestrial intelligence (SETI).

10. Studying the impact of solar flares on Earth’s magnetic field.

11. Investigating the history of space exploration.

12. Analyzing the concept of time dilation in relativity.

Psychology Research Topics

Discover the psychology research topics for students:

1. Investigating the effects of mindfulness meditation on stress reduction.

2. Studying the impact of early childhood experiences on adult behavior.

3. Analyzing the relationship between sleep patterns and mood.

4. Exploring the psychology of decision-making under uncertainty.

5. Investigating the effects of music therapy on patients with Alzheimer’s disease.

6. Studying the role of empathy in interpersonal relationships.

7. Analyzing the psychology of fear and phobias.

8. Investigating the effects of social isolation on mental health.

9. Exploring the influence of advertising on consumer behavior.

10. Studying the psychology of memory and recall.

11. Investigating the relationship between personality traits and career choices.

12. Analyzing the effects of social media on self-esteem.

Earth Science Research Topics

Here are some scientific research topics for high school students in earth science:

1. Studying the formation of earthquakes and their impact on landscapes.

2. Investigating the processes of erosion and sedimentation in rivers.

3. Analyzing the effects of climate change on glacial retreat.

4. Exploring the formation of volcanoes and their eruptions.

5. Investigating the geology of a specific region.

6. Studying the impact of tsunamis on coastal communities.

7. Analyzing the properties of different types of rocks and minerals.

8. Investigating the formation of caves and underground formations.

9. Exploring the processes of weathering and soil formation.

10. Investigating the geological history of a particular mountain range.

11. Studying the impact of wildfires on ecosystems and soil.

12. Analyzing the effects of climate change on the availability of freshwater resources.

Engineering and Technology Research Topics

Let’s dive into the engineering and technology research topics for high school students:

1. Investigating the efficiency of solar panels in different weather conditions.

2. Studying the aerodynamics of different wing designs in model airplanes.

3. Analyzing the impact of 3D printing on manufacturing processes.

4. Exploring the development of sustainable building materials.

5. Investigating the use of artificial intelligence in autonomous vehicles.

6. Studying the effectiveness of water purification methods.

7. Analyzing the design and performance of wind turbines.

8. Investigating the development of wearable health monitoring devices.

9. Exploring the use of drones for environmental monitoring.

10. Studying the impact of cybersecurity threats on modern technology.

11. Investigating the design and efficiency of energy-efficient homes.

12. Analyzing the potential of blockchain technology in various industries.

13. Investigating the impact of 5G technology on wireless communication networks.

Health and Medicine Research Topics

Discover the scientific research topics for high school students in health and medicine:

1. Investigating the effects of different types of exercise on physical fitness.

2. Studying the impact of nutrition on weight management.

3. Analyzing the relationship between sleep patterns and overall health.

4. Exploring the effectiveness of alternative medicine treatments.

5. Investigating the genetics of a specific medical condition.

6. Studying the effects of stress on the immune system.

7. Analyzing the impact of vaccinations on public health.

8. Investigating the use of telemedicine in healthcare delivery.

9. Exploring the factors influencing antibiotic resistance.

10. Studying the psychology of pain perception.

11. Investigating the effects of environmental pollutants on human health.

12. Analyzing the relationship between diet and chronic diseases.

13. Studying the potential benefits of gene therapy in treating genetic diseases.

Mathematics and Computer Science Research Topics

Let’s explore the mathematics and computer research topics for high school students:

1. Investigating the properties of prime numbers and their applications.

2. Studying the algorithms used in data encryption.

3. Analyzing the efficiency of sorting algorithms.

4. Exploring the applications of artificial intelligence in image recognition.

5. Investigating the mathematics of fractals and their visual representations.

6. Studying the use of data mining in predicting consumer behavior.

7. Analyzing the algorithms used in recommendation systems.

8. Investigating the mathematics of network theory.

9. Exploring the applications of game theory in decision-making.

10. Studying the mathematics behind cryptography.

11. Investigating the use of machine learning in natural language processing.

12. Analyzing the algorithms used in optimizing transportation routes.

13. Analyzing the applications of quantum computing in solving complex problems.

Tips for Conducting Scientific Research Topics for High School Students

Before you embark on your research journey, consider these tips:

Define clear research objectives.
Seek guidance from teachers or mentors.
Maintain organized records of your work.
Stay persistent and embrace failure as a learning opportunity.

Engaging in scientific research topics for high school students can be an incredibly rewarding experience. It allows you to explore your interests, develop critical skills, and contribute to our collective understanding of the world. When selecting a research topic, remember to choose something that genuinely excites you, is relevant to your field of interest, and is feasible given your available resources.

Whether you’re passionate about biology , chemistry, physics, social sciences, or any other field, there’s a fascinating research topic waiting for you to explore. So, roll up your sleeves, ask questions, and embark on your scientific research journey—it’s an adventure that can shape your future and the world around you.

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100 Amazing Physics Research Topics and Ideas

Table of Contents

Physics is a discipline of science that studies the properties of energy and matter. If you are pursuing a degree in Physics, you will most likely be required to submit a thesis on the latest physics research topics. In general, physics is a broad field of study that is divided into several branches and sub-branches such as classical physics, modern physics, thermodynamics, quantum physics, atomic physics, and so on. Hence, for preparing a physics research paper, you may choose any topic from its branches.

Usually, when the subject is wide, it might be tough for you to pick one appropriate topic for research. However, with our support, you can easily cross this challenge. Especially, to make the topic selection easier for you, in this blog, we have presented a list of 100 outstanding physics research paper topics and ideas as suggested by experts. Additionally, we have also shared how to choose a good topic for physics research.

Continue reading this blog and get exclusive physics research ideas.

Know How to Select a Physics Research Topic

The topic you pick plays a major role in the success of your research paper. Therefore, make sure to identify an appropriate physics research topic to get started. In case, you are unsure how to choose the right topic for a physics research paper, follow these steps.

Determine the area of physics you are passionate about researching. For instance, you can conduct research on any topic related to areas such as classical physics, thermodynamics, astrophysics, etc but it should fall within your interest.
In the chosen area, explore the existing literature and gather possible physics research ideas. Particularly, to collect ideas, you may take references from relevant articles, and journals.
Analyze all the gathered ideas and narrow down the list based on its research scope. If a topic is too broad to cover within the deadline, divide them into subtopics.
Once again review the shortlisted ideas and pick a physics research topic that is unique, flexible, feasible, and meets the standard research guidelines. Note that, the topic you select should have enough resources and it should allow you to prove your thesis statement with valid evidence.
After you have chosen an ideal topic, discuss it with your supervisor and get their feedback. Their guidance may help you to improve your study.

Also Read: 100 Excellent Psychology Research Topics and Ideas

List of the Best Physics Research Topics

Are you struggling to find a topic for physics research? If yes, then feel free to explore the list published below and pick any topic that meets your needs. In the list, we have added 100 amazing research topics and ideas on different branches and sub-branches of physics.

Classical Physics Research Topics

Discuss the Novaya Zemlya Effect.
Explain the causes of surface tension.
Study the various types of mechanical waves.
Discuss the working of induction stoves.
Explain the workings of buoyancy.
Explain how sound travels.
Analyze Einstein’s Theory of Relativity.
Explain the significance of Heisenberg’s Uncertainty Principle.
Examine the uses of electromagnetic waves.
Investigate what happens when an object absorbs light.

Theoretical Physics Research Topics

Explore the ways kinetic theory explains the macroscopic properties of gas.
Study the Feynman diagram.
Compare the different types of Gauge theories.
Explain the M-theory.
Explore the detectability of the Dark Matter.
Examine the different applications of topological insulators.
Take a look at Time Reversal Symmetry in Quantum Mechanics.
Explain the conservation of angular momentum.
Compare the thermodynamic Debye model and the Einstein model.
Explore the different predictions of quantum field theory on curved space-time.

Nuclear Physics Research Topics

Examine the effects of nuclear physics on medical imaging technology.
Investigate the role of mesons in nuclear forces.
Explore the recent developments in laser spectroscopy.
Conduct a theoretical analysis of the nuclear decay process.
Examine nuclear reactions besides the Coulomb barrier.
Study the synthesis of superheavy elements.
Explore nuclear waste management and disposal strategies.
Study nuclear reactions in supernovae.
Explore nuclear isomerism for quantum computing.
Investigate the mechanism of heavy ion reactions.

Atomic Physics Research Paper Topics

Analyze the impact of Quantum Entanglement on information transfer.
Evaluate the influence of atomic physics on biological systems.
Examine the role of atomic physics in climate change studies.
Explore the properties of exotic atoms.
Evaluate the role of atomic physics in quantum cryptography.
Explore the applications of atomic physics in emerging technologies.
Study the advancements in atom interferometry and precision measurements.
Explain the role of atomic physics in the future of nanotechnology.
Analyze the influence of quantum magnetism on atomic structures.
Study the theoretical frameworks for describing atomic structure and behavior.

Thermodynamics Research Topics

Examine the implications of thermodynamics in the formation of stars.
Explore the role of thermodynamics in the recovery of resources from waste.
Analyze the influence of thermodynamics in climate change modeling.
Explore the effects of thermodynamics in food processing and nutrient preservation.
Discuss the applications of thermodynamics in renewable energy technology.
Explore thermodynamic limits of computation.
Analyze the mysteries of black hole thermodynamics.
Exploit thermodynamics for efficient spacecraft heat management.
Explore thermodynamics in Quantum Information Theory.
Study advanced materials in heat engines from a thermodynamic perspective.

Astrophysics Research Paper Topics

Examine the quantum effects in stellar evolution.
Study dark matter distribution in galaxy clusters.
Explore the elements responsible for X-ray production in space.
Study the main controversies in astrophysics.
Investigate the amount of energy produced by Gamma-ray bursts.
Compare Neutron stars and pulsars.
Take a closer look at the latest developments in astrophysics.
Explore how scientists look at black holes.
Analyze the results and effects of gravitational waves.
Take a look at magnetic fields in galactic centers.

Also Read: Top 100 Forensic Psychology Research Topics and Ideas

Physical Geography Research Topics

Examine the causes of riptides.
Analyze the effects of high altitude on vegetation
Investigate the various atmospheric changes that happened over the last 100 years.
Analyze the effects of Tsunamis on coastal landforms.
Explain the physics behind the formation of glaciers.
Analyze the influence of Tectonic Plate movements on geographical features.
Examine the impact of solar radiation on geographical landform evolution.
Discuss the role of oceanic currents in coastal erosion.
Examine the impact of earthquakes on geographical landforms.
Analyze the various reasons for landslides.

Statistical Physics Research Ideas

Study statistical mechanics in biophysical systems.
Examine the impact of fractal analysis on statistical physics.
Study the applications of statistical physics in neural networks.
Discuss the statistical significance of quantum fluctuations.
Investigate spin glasses and disorder in statistical physics.
Explore non-equilibrium statistical mechanics in living systems.
Discuss the role of statistical physics in ecosystem dynamics.
Solve the puzzle of quantum entanglement using statistical methods.
Study phase transitions in quantum fields.
Examine the statistical physics approach to comprehend traffic flow dynamics.

Particle Physics Research Topics

Discuss the applications of particle physics in medicine.
Explain the use of particle physics in treating cancer.
Study gauge theories in particle physics.
Find out the secrets of cosmic ray particles.
Examine the asymmetry between matter and antimatter.
Study the ramifications of antiparticle behavior for symmetry.
Examine string theory applications in particle physics.
Explore the influence of dark matter particles on cosmic structures.
Discuss the role of magnetic monopoles in particle physics.
Take a closer look at Pentaquark particles.

Physics Research Ideas on Quantum Mechanics

Explore the role of quantum mechanics in quantum computing.
Investigate the quantum mechanics of quantum dots in optoelectronic devices.
Examine the EPR paradox and the implications of quantum mechanics
Analyze the quantum mechanics of spintronics for information storage and processing.
Explore the role of quantum mechanics in quantum sensing and metrology.
Examine the quantum mechanics of quantum optics.
Build quantum simulators for studying complex quantum systems.
Analyze the quantum mechanics of the quantum hall effect.
Evaluate quantum coherence in macroscopic systems.
Explore the applications of quantum chaos in quantum mechanics.

Wrapping Up

All the ideas recommended above will help you to come up with a high-quality physics research paper deserving of an A+ grade. In case, you require expert help with physics research paper topic selection, writing, and proofreading, reach out to us immediately.

At greatassignmenthelp.com, to offer you online assignment writing help, we have several talented academic writers with strong knowledge of Physics. By using their expertise, according to your requirements, they will assist you in crafting your physics research paper accurately with no traces of plagiarism. Furthermore, by utilizing our physics assignment help services, you may complete your project before the due date and achieve top scores.

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50 High School Senior Thesis Topics [PDF Included]

As high school seniors approach the end of their academic journey, one final task stands before them: the senior thesis. This capstone project is a culmination of their years of learning and provides an opportunity to delve deeply into a topic of their choosing. The senior thesis is a chance for students to showcase their research, writing, and analytical skills, as well as their creativity and intellectual curiosity.

With so many potential research topics to explore, the senior thesis is a unique and exciting opportunity for high school seniors to leave their mark on the academic world. In this article, we will explore some of the most interesting and engaging high school senior thesis topics, and offer tips on how to choose the right topic for you.

Unleashing the Creative Minds: Exciting thesis ideas for high schoolers

Much like satire essay topics , literacy essay topics , and biology research topics , the topics given below cover a wide range of subjects, from science and technology to art, and literature. They are intended to inspire high school seniors to think critically and explore their interests in depth.

Students can choose a topic that resonates with them and conduct research to gain a deeper understanding of the subject matter. Each topic has its unique significance and can lead to interesting and thought-provoking insights that can contribute to the larger body of knowledge on the subject.

1. The effects of social media on mental health:

With the rise of social media, there is growing concerned about its impact on mental health, making this an important and timely topic to explore.

2. The impact of climate change on local ecosystems:

Climate change is an urgent global issue that has significant impacts on local ecosystems, making this topic highly relevant.

3. The history and impact of jazz music:

Jazz is a uniquely American art form that has had a profound impact on music and culture worldwide, making it an interesting and important topic for exploration.

4. The effects of caffeine on the human body:

Caffeine is a commonly consumed substance with a range of effects on the body, making this topic both interesting and relevant.

5. The causes and consequences of income inequality:

Income inequality is a significant societal issue with far-reaching consequences, making this an important topic for exploration.

6. The role of technology in education:

Technology is rapidly transforming education, and understanding its impact on learning is crucial for shaping the future of education.

7. The history and significance of the Civil Rights Movement:

The Civil Rights Movement was a defining moment in American history that continues to shape our society today, making it a compelling and important topic for study.

8. The impact of fast food on public health:

Fast food is a ubiquitous part of modern life with potentially significant health consequences, making this topic both interesting and relevant.

9. The portrayal of gender roles in media:

The media plays an important role in shaping societal attitudes toward gender, making this a timely and important topic for exploration.

10. The history and significance of the Olympic Games:

The Olympic Games are a celebrated global event with a rich history and cultural significance, making them a fascinating topic for study.

11. The effects of sleep deprivation on academic performance:

Sleep is crucial for academic success, and understanding its effects on performance is important for students and educators alike.

12. The role of art in society:

Art has the power to inspire, challenge, and transform society, making this a fascinating and important topic for exploration.

13. The history and impact of hip-hop music:

Hip-hop is a cultural phenomenon that has had a significant impact on music, fashion, and society, making it an interesting and important topic for study.

14. The impact of social class on education:

Social class can have a significant impact on educational opportunities and outcomes, making this a relevant and important topic for exploration.

15. The impact of globalization on culture:

Globalization is reshaping culture in a complex and sometimes unexpected ways, making this a fascinating and important topic for study.

16. The effects of exercise on mental health:

Exercise has been shown to have significant mental health benefits, making this an important topic for exploration.

17. The role of government in protecting the environment:

Governments play a crucial role in protecting the environment, making this a relevant and important topic for exploration.

18. The impact of video games on cognitive development:

Video games are a popular form of entertainment with potentially significant impacts on cognitive development, making this topic both interesting and relevant.

19. The impact of social media on political activism:

Social media has been a powerful tool for political activism in recent years, making this topic both timely and important for exploration.

20. The history and impact of rock music:

Rock music is a genre with a rich history and cultural significance, making it an interesting and important topic for study.

21. The effects of stress on physical health:

Stress can have significant impacts on physical health, making this topic both relevant and important for exploration.

22. The impact of immigration on society:

Immigration has shaped societies throughout history, and understanding its impact is crucial for understanding our world today.

23. The role of art in political activism:

Art can be a powerful tool for political activism, making this a timely and important topic for exploration.

24. The effects of technology on human communication:

Technology is rapidly transforming the way we communicate, making this topic both interesting and relevant.

25. The impact of social media on self-esteem:

Social media has been shown to have both positive and negative effects on self-esteem, making this a relevant and important topic for study.

26. The effects of childhood obesity on health outcomes:

Childhood obesity is a growing public health concern with significant health consequences, making this an important topic for exploration.

27. The history and impact of punk rock music:

Punk rock is a genre with a unique history and cultural significance, making it an interesting and important topic for exploration.

28. The effects of mindfulness meditation on mental health:

Mindfulness meditation has been shown to have significant mental health benefits, making this an important topic for study.

28. The impact of technology on privacy:

Technology has transformed the way we think about privacy, making this a relevant and important topic for study.

29. The history and impact of reggae music:

Reggae is a genre with a rich history and cultural significance, making it an interesting and important topic for exploration.

30. The effects of social support on mental health:

Social support can have significant mental health benefits, making this an important topic for study.

31. The portrayal of beauty standards in media:

The media plays a powerful role in shaping societal attitudes toward beauty, making this an important and timely topic for exploration.

32. The impact of social media on romantic relationships:

Social media has transformed the way we navigate romantic relationships, making this topic both interesting and relevant.

33. The role of technology in modern art:

Technology is transforming the way we create and experience art, making this a fascinating and important topic for study.

34. The impact of social class on health outcomes:

Social class can have a significant impact on health outcomes, making this a relevant and important topic for exploration.

35. The history and impact of the Civil Rights Act of 1964:

The Civil Rights Act of 1964 was a landmark piece of legislation with profound impacts on American society, making it an important and compelling topic for study.

36. The effects of peer pressure on academic performance:

Peer pressure can have both positive and negative impacts on academic performance, making this a relevant and important topic for exploration.

37. The impact of climate change on global health:

Climate change has significant impacts on global health, making this a timely and important topic for exploration.

38. The effects of music on memory and cognitive function:

Music has been shown to have both short- and long-term effects on memory and cognitive function, making this an interesting and important topic for study.

39. The impact of technology on education:

Exploring the role of online learning platforms and digital tools in enhancing student learning outcomes.

40. Critical thinking skills in higher education:

Examining the factors that promote the development of critical thinking skills among college students.

41. Teacher-student relationships and academic achievement:

Investigating the impact of positive teacher-student relationships on academic performance.

42. The impact of parental involvement on academic achievement:

Examining the ways in which parental involvement can positively impact academic performance.

43. Learning styles and student achievement:

Investigating the relationship between individual learning styles and academic achievement.

44. The role of motivation in student success:

Exploring the importance of motivation in academic achievement.

45. The effects of socioeconomic status on academic achievement:

Examining the relationship between socioeconomic status and academic performance.

46. Cross-cultural differences in academic achievement:

Investigating how cultural diversity can impact academic achievement.

47. The impact of standardized testing on student learning:

Examining the effectiveness of standardized testing as a measure of student achievement.

48. Teaching methods and student engagement:

Exploring the relationship between different teaching methods and student engagement in learning.

49. The impact of classroom environment on student learning:

Examining how the physical and social environment of the classroom can impact student learning outcomes.

50. Teacher burnout and turnover:

Investigating the factors that contribute to teacher burnout and turnover, and the impact on student achievement.

All work and no play makes jack a dull boy: How to make your thesis journey fun?

Writing a thesis can be a long and challenging journey that requires a significant amount of time, effort, and dedication. However, it’s important to remember that taking breaks and finding ways to make the process more enjoyable can help you stay motivated and focused. At the same time, it is often there on every high schooler’s bucket list. Here are some tips to make your thesis journey more fun:

Break it down into smaller tasks: Writing a thesis can seem overwhelming, but breaking it down into smaller tasks can help make it more manageable. You can start by creating a list of tasks and prioritizing them based on importance and deadlines. Then, focus on completing one task at a time, rather than thinking about the entire thesis at once.
Set achievable goals: Setting goals that are realistic and achievable is important to maintain your motivation and focus. You can set daily, weekly, or monthly goals, depending on your needs and timeline. Celebrating each milestone can help boost your confidence and encourage you to keep going.
Create a supportive community: It can be helpful to have a supportive community while working on your thesis. You can join a study group, create a writing group with peers, or seek a mentor to provide guidance and support. Having people who understand what you’re going through can help you feel less alone and motivate you to keep working.
Find a comfortable workspace: Your workspace can have a big impact on your productivity and focus. Find a space that is comfortable and free from distractions. Make sure your desk and chair are at the right height, and that you have adequate lighting. A clutter-free workspace can also help you feel more organized and focused.
Take breaks: Taking regular breaks is important to avoid burnout and maintain your focus. You can take short breaks throughout the day to stretch, meditate, or take a walk. Longer breaks, such as a weekend getaway, can also help you recharge and come back to your work with fresh energy.
Mix it up: Sometimes, changing your routine can help you stay engaged and focused. You can experiment with different writing techniques, such as brainstorming, mind-mapping, or freewriting. Changing your study location can also help, such as working from a café, library, or park. Listening to music or using different background noises can also help you stay focused.
Reward yourself: Setting up a reward system can help you stay motivated and give you something to look forward to. You can reward yourself for completing a task, reaching a milestone, or sticking to your study schedule. Rewards can be small, such as a favorite snack or a movie, or larger, such as a weekend trip or a spa day.

In conclusion, high school senior thesis topics can be a great way for students to explore their interests and develop critical thinking skills. These topics cover a wide range of subjects and can lead to fascinating insights and discoveries. By conducting research and writing a thesis, students can gain a deeper understanding of their chosen topic and contribute to the larger body of knowledge on the subject.

Whether exploring social issues, science, technology, art, or literature, there is a topic out there for every student to delve into and make their own. By choosing a topic that resonates with them and putting in the work to create a well-researched and thoughtful thesis, high school seniors can develop valuable skills and gain a sense of accomplishment and pride in their work.

Having a 10+ years of experience in teaching little budding learners, I am now working as a soft skills and IELTS trainers. Having spent my share of time with high schoolers, I understand their fears about the future. At the same time, my experience has helped me foster plenty of strategies that can make their 4 years of high school blissful. Furthermore, I have worked intensely on helping these young adults bloom into successful adults by training them for their dream colleges. Through my blogs, I intend to help parents, educators and students in making these years joyful and prosperous.

Dissertations / Theses on the topic 'High school physics'

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Kavaz, Sevim. "Analysis Of High School Physics Textbooks." Master's thesis, METU, 2006. http://etd.lib.metu.edu.tr/upload/2/12607693/index.pdf.

Bahcivan, Eralp. "Assessment Of High School Physics Teachers." Phd thesis, METU, 2012. http://etd.lib.metu.edu.tr/upload/12614413/index.pdf.

Checkley, Doug, and University of Lethbridge Faculty of Education. "High school students' perceptions of physics." Thesis, Lethbridge, Alta. : University of Lethbridge, Faculty of Education, 2010, 2010. http://hdl.handle.net/10133/2584.

Eiser, Leslie Agrin. "Microcomputer graphics to teach high school physics." Thesis, McGill University, 1985. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=66055.

Kapucu, Serkan. "Physics Teachers." Phd thesis, METU, 2012. http://etd.lib.metu.edu.tr/upload/12614422/index.pdf.

Wallace, Michelle L. Ellerton Nerida F. "Characterization of high school mathematics and physics language genres." Normal, Ill. : Illinois State University, 2004. http://wwwlib.umi.com/cr/ilstu/fullcit?p3127139.

Dogan, Tekiroglu Ozlem. "Explaining The Relationship Between High School Students&#039." Master's thesis, METU, 2005. http://etd.lib.metu.edu.tr/upload/12606243/index.pdf.

White, Richard Neal. "A high school physics instructor's website: Design, implementation, and evaluation." CSUSB ScholarWorks, 2002. https://scholarworks.lib.csusb.edu/etd-project/2062.

Stirewalt, Heather R. "Computation as a Model Building Tool in a High School Physics Classroom." Thesis, California State University, Long Beach, 2018. http://pqdtopen.proquest.com/#viewpdf?dispub=10785706.

The Next Generation Science Standards (NGSS) have established computational thinking as one of the science and engineering practices that should be developed in high school classrooms. Much of the work done by scientists is accomplished through the use of computation, but many students leave high school with little to no exposure to coding of any kind. This study outlines an attempt to integrate computational physics lessons into a high school algebra-based physics course which utilizes Modeling Instruction. Specifically, it aims to determine if students who complete computational physics assignments demonstrate any difference in understanding force concepts as measured by the Force Concept Inventory (FCI) versus students who do not. Additionally, it investigates students’ attitudes about learning computation alongside physics. Students were introduced to Vpython programs during the course of a semester. The FCI was administered pre and post instruction, and the gains were measured against a control group. The Computational Modeling in Physics Attitudinal Student Survey (COMPASS) was administered post instruction and the responses were analyzed. While the FCI gains were slightly larger on average than the control group, the difference was not statistically significant. This at least suggests that incorporating computational physics assignments does not adversely affect students’ conceptual learning.

Fischman, Lane Ari. "Using Gardner's multiple intelligence theory to differentiate high school physics instruction." Montana State University, 2011. http://etd.lib.montana.edu/etd/2011/fischman/FischmanL0811.pdf.

Lynn, Hermes B. "Guided inquiry using the 5E instructional model with high school physics." Montana State University, 2012. http://etd.lib.montana.edu/etd/2012/lynn/LynnH0812.pdf.

Bermudez, Julia V. "Examining the effects of physics second on high school science achievement." Thesis, California State University, Long Beach, 2014. http://pqdtopen.proquest.com/#viewpdf?dispub=1527677.

In 2007 Pioneer High School, a public school in Whittier, California changed the sequence of its science courses from the Traditional Biology-Chemistry-Physics (B-C-P) to Biology-Physics-Chemistry (B-P-C), or "Physics Second." The California Standards Tests (CSTs) scores in Physics and Chemistry from 2004-2012 were used to determine if there were any effects of the Physics Second sequencing on student achievement in those courses. The data was also used to determine whether the Physics Second sequence had an effect on performance in Physics and Chemistry based on gender.

Independent t tests and chi-square analysis of the data determined an improvement in student performance in Chemistry but not Physics. The 2x2 Factorial ANOVA analysis revealed that in Physics male students performed better on the CSTs than their female peers. In Chemistry, it was noted that male and female students performed equally well. Neither finding was a result ofthe change to the "Physics Second" sequencing.

Negishi, Meiko. "A cross-cultural, multilevel study of inquiry-based instruction effects on conceptual understanding and motivation in physics." Diss., Mississippi State : Mississippi State University, 2007. http://library.msstate.edu/etd/show.asp?etd=etd-03302007-095858.

Davies, Thomas Robert. "Effects of structured cooperative learning groups in a high school physics classroom." Montana State University, 2012. http://etd.lib.montana.edu/etd/2012/davies/DaviesT0812.pdf.

Wessel, Warren Edward. "Knowledge construction in high school physics, a study of student/teacher interaction." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 1998. http://www.collectionscanada.ca/obj/s4/f2/dsk3/ftp04/nq35822.pdf.

Roy, Suparna S. "The complex classrooms of three award-winning Ontario high school physics teachers." Thesis, Kingston, Ont. : [s.n.], 2007. http://hdl.handle.net/1974/453.

Eryilmaz, Hulya. "The Effect Of Peer Instruction On High School Students&#039." Phd thesis, METU, 2004. http://etd.lib.metu.edu.tr/upload/12604702/index.pdf.

Gao, Lingbiao. "Conceptions of teaching held by school physics teachers in Guangdong China and their relations to student learning /." Hong Kong : University of Hong Kong, 1998. http://sunzi.lib.hku.hk/hkuto/record.jsp?B20540760.

Arner, John De Jong. "The development of an instrument to aid in focusing on modern physics in the high school physics classroom." CSUSB ScholarWorks, 1995. https://scholarworks.lib.csusb.edu/etd-project/1003.

McClure, Patricia Head. "Computer-related technology use in the high school physics classroom : a case study /." Diss., This resource online, 1996. http://scholar.lib.vt.edu/theses/available/etd-10022007-145118/.

Caramaschi, Martina. "Applications of RFN (Reconceptualized Family resemblance approach to Nature of science) to high school physics teaching." Master's thesis, Alma Mater Studiorum - Università di Bologna, 2020. http://amslaurea.unibo.it/21708/.

Nashon, Samson Madera. "Teaching and learning high school physics through analogies, case study of Kenyan classrooms." Thesis, National Library of Canada = Bibliothèque nationale du Canada, 2001. http://www.collectionscanada.ca/obj/s4/f2/dsk3/ftp04/NQ58950.pdf.

Guisti, Brett M. "Comparison of Guided and Open Inquiry Instruction in a High School Physics Classroom." Diss., CLICK HERE for online access, 2008. http://contentdm.lib.byu.edu/ETD/image/etd2572.pdf.

Qazi, Fawzia Bibi. "An Effective High School Inquiry-Based Physics First Curriculum: Student and Alumni Perceptions." Digital Commons at Loyola Marymount University and Loyola Law School, 2019. https://digitalcommons.lmu.edu/etd/897.

Eryılmaz, Hülya. "The effect of peer instruction on high school students' achievement and attıtudes toward physics." Ankara : METU, 2004. http://etd.lib.metu.edu.tr/upload/12604702/index.pdf.

Al-Ahmadi, Fatheya Mahmood. "The development of scientific thinking with senior school physics students." Thesis, Connect to e-thesis, 2008. http://theses.gla.ac.uk/241/.

Qian, Lingbo. "Comparing US and Chinese High-School Physics Teaching in Terms of the Use of Inquiry." Wright State University / OhioLINK, 2012. http://rave.ohiolink.edu/etdc/view?acc_num=wright1346393007.

Welling, Jonathan Jacob. "Parent Reciprocal Teaching: Comparing Parent and Peer Reciprocal Teaching in High School Physics Instruction." BYU ScholarsArchive, 2018. https://scholarsarchive.byu.edu/etd/6883.

Maia, Marcilon Chaves. "An approach of the standard model of particle physics accesible to high school students." Universidade Federal do CearÃ, 2011. http://www.teses.ufc.br/tde_busca/arquivo.php?codArquivo=6715.

Asp, Fredrik, and Leif Andersson. "New technology in physics : A study in how to integrate new technology and research in physics education in secondary high school." Thesis, Jönköping University, School of Education and Communication, 2008. http://urn.kb.se/resolve?urn=urn:nbn:se:hj:diva-1131.

Youths do not reflect over how it works but rather focus on how they can use the technology. Earlier research has studied if teacher acquires further education in there topics, not if knowledge about new technology can contribute to a better education. If teachers have good knowledge about new technology and forwarding it to the pupils, can it increase the interest for physics among the pupils? Didactic research has shown that pupils would like to see conjunction with the knowledge they receives and their natural world. Didactic research concentrates on how knowledge is forwarding and not on the subject for the education. Six teachers on six different schools has been interview. On three of these schools has also five pupils been interview on their opinion on if and how new technology has be taken up in their education. New technology is being taken up in the physics education, but it exist no recommendation on how. New technologies are being taken up on the teacher’s initiative, paramountly for that rouse interest at pupils or connect the physics to the pupil's reality. Pupils receive also explanations of new technology when they put questions about it during lessons. The teacher’s apprehension about what is new technology varies. Common for all teachers is that they request better knowledge of their subjects of teaching for that being able to take up new technology with the pupils. They pupils that have interviewed thinks that it is good if new technology is being taken up in the physics education, it gives a better connection to reality.

Ungdomar reflekterar inte i första hand över hur ny teknik fungerar utan fokuserar på hur man kan använda tekniken. Tidigare forskning har studerat om lärare behöver ämnesfortbildning, inte om kunskap om ny teknik kan bidra till en bättre undervisning. Om läraren har god kunskap om ny teknik och förmedlar det till eleverna kan det då öka intresset för fysik hos eleverna? Didaktisk forskning har visat att elever vill se samband mellan den kunskap de får och deras omvärld. Didaktisk forskning inriktas på hur kunskap förmedlas och inte på ämnet i undervisningen. Sex lärare på sex olika skolor har intervjuats. På tre av dessa skolor har också fem elever intervjuats för att ge sin syn på om de anser att ny teknik tas upp i undervisningen. Studien visar på att ny teknik tas upp i fysikundervisningen, men det finns inga rekommendationer på hur. Ny teknik tas främst upp på lärarens initiativ, främst för att väcka intresse hos elever men också för att koppla fysiken till elevens verklighet. Elever får även förklaringar av ny teknik när de ställer frågor om den under lektioner. Lärares uppfattning om vad som är ny teknik varierar. Lärare efterfrågar bättre ämneskunskaper för att kunna ta upp ny teknik med eleverna. De elever som har intervjuats tycker det är bra om ny teknik tas upp i fysikkurserna, det ger en bättre koppling till verkligheten.

DePalma, Darlene. "AN ANALYSIS OF PREDICTORS OF ENROLLMENT AND SUCCESSFUL ACHIEVEMENT FOR GIRLS IN HIGH SCHOOL ADVANCED PLACEMENT PHYSICS." Doctoral diss., University of Central Florida, 2008. http://digital.library.ucf.edu/cdm/ref/collection/ETD/id/2502.

Ritter, Mary Seabrook. "The effects of interactive engagement on motivation, participation and conceptual understanding in high school physics." Montana State University, 2011. http://etd.lib.montana.edu/etd/2011/ritter/RitterM0811.pdf.

Rytting, Matthew Charles. "Comparison of Simulation and Hands-On Labs in Helping High School Students Learn Physics Concepts." BYU ScholarsArchive, 2016. https://scholarsarchive.byu.edu/etd/6132.

Test, Harold G. (Harold Goldson). "A Comparison of Physics Enrollments in Selected Large Texas Secondary Schools." Thesis, North Texas State University, 1985. https://digital.library.unt.edu/ark:/67531/metadc331038/.

Suklevska, Karolina. "Lärande och Utomhuspedagogik i Fysik på högstadiet (Learning and Outdoor Education in Physics at high school)." Thesis, Malmö högskola, Lärarutbildningen (LUT), 2013. http://urn.kb.se/resolve?urn=urn:nbn:se:mau:diva-27986.

Diez, Diana. "Promoting conceptual understanding in high-school physics : Exploring the effects of using an audience response system." Thesis, KTH, Lärande, 2021. http://urn.kb.se/resolve?urn=urn:nbn:se:kth:diva-290231.

高凌飆 and Lingbiao Gao. "Conceptions of teaching held by school physics teachers in Guangdong China and their relations to student learning." Thesis, The University of Hong Kong (Pokfulam, Hong Kong), 1998. http://hub.hku.hk/bib/B31238488.

Slykhuis, David Alan. "The Efficacy of World Wide Web-Mediated Microcomputer-Based Laboratory Activities in the High School Physics Classroom." NCSU, 2004. http://www.lib.ncsu.edu/theses/available/etd-03242004-153352/.

Nicol, Marsha Lynn Paulus. "Examining the changing beliefs of a high school physics teacher integrating mathematics through technology : a case study /." Connect to resource, 1995. http://rave.ohiolink.edu/etdc/view.cgi?acc%5Fnum=osu1244833504.

Scannell, Stephen Godfrey. "Next Generation Science Standards and Physics First: a Case Study of High School Teachers' Beliefs and Practices." PDXScholar, 2019. https://pdxscholar.library.pdx.edu/open_access_etds/5002.

Jensen, Edvin. "The Impact of Interactive Touchscreens in Physics Education in Upper Secondary School : A systematic literature review." Thesis, Linköpings universitet, Institutionen för fysik, kemi och biologi, 2018. http://urn.kb.se/resolve?urn=urn:nbn:se:liu:diva-150344.

Ibrahim, Mustafa Mohamed. "The Impact of Computer Simulation on the Development of the Inquiry Skills of High School Students in Physics." Thesis, Université d'Ottawa / University of Ottawa, 2011. http://hdl.handle.net/10393/19796.

Aiken, John M. "Transforming High School Physics With Modeling And Computation." 2013. http://scholarworks.gsu.edu/phy_astr_theses/18.

Taft, Tanya Marie. "Curriculum integration in senior high school physics courses." Thesis, 2007. http://hdl.handle.net/1828/272.

Feng, Wei, and 馮韡. "ANALYSIS OF MODELS IN HIGH SCHOOL PHYSICS TEXTBOOKS." Thesis, 2018. http://ndltd.ncl.edu.tw/handle/tsg4dt.

YU, YAUN-CHENG, and 原佑誠. "Analysis of Physics Models in Junior High School Textbooks." Thesis, 2019. http://ndltd.ncl.edu.tw/handle/jsmt3t.

Ching-Jang, Lo, and 羅慶璋. "Network-Based Virtual Physics Experiments for Junior High School Students." Thesis, 2004. http://ndltd.ncl.edu.tw/handle/80955377074073181739.

王文良. "Junior High School Students'' Expectancy of the Physics-Chemistry Teachers." Thesis, 1997. http://ndltd.ncl.edu.tw/handle/39622320725906401464.

邱銘鴻. "Small Group Learning with Digital Pens in High School Physics." Thesis, 2012. http://ndltd.ncl.edu.tw/handle/02145009255338004780.

Liou, Hong-Gu, and 劉虹谷. "An Analysis of Historical Contents in High School Physics Textbooks." Thesis, 2016. http://ndltd.ncl.edu.tw/handle/71731095980132402626.

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Harvard phd theses in physics, 2001-.

BAILEY, STEPHEN JOHN, B.S. (Washington) 1995. A Study of B → J/y K (*)0 X Decays. (Huth)

CHEN, LESTER HAO-LIN, B.S. (Duke) 1995. (Harvard) 1999. Charge-Iimaging Field-Effect Transistors for Scanned Probe Microscopy. (Westervelt)

CHOU, YI, B.S. (National Tsing Hua University) 1988. (National Tsing Hua University) 1990. Developments of EXITE2 and Timing Analysis of Ultra-Compact X-ray Binaries. (Papaliolios/Grindlay)

ERSHOV, ALEXEY, B.S. (Moscow Institute of Physics & Technology) 1996. Beauty Meson Decays to Charmonium. (Feldman)

FOX, DAVID CHARLES, A.B. (Princeton) 1991. (Harvard) 1994. The Structure of Clusters of Galaxies. (Loeb)

FUKUTO, MASAFUMI, B.S. (Oregon) 1994. (Harvard) 1997). Two-Dimensional Structures and Order of Nano-Objects on the Surface of Water: Synchrotron X-ray Scattering Studies. (Pershan)

HILL, MARC, B.S. (Illinois) 1994. Experimental Studies of W-band Accelerator Structures at High Field. (Huth)

KANNAPPAN, SHEILA, A.B. (Harvard) 1991. (Harvard, History of Science) 2001. Kinematic Clues to the Formation and Evolution of Galaxies. (Horowitz)

LAU, CHUN-NING, B.A. (Chicago) 1994. (Harvard) 1997. Quantum Phase Slips in Superconducting Nanowires. (Tinkham)

OSWALD, JOSEPH ANTON, B.S. (Duke) 1992. (Harvard) 1995. Metallo-dielectric Photonic Crystal Filters for Infrared Applications. (Verghese/Tinkham)

SCHAFFER, CHRISTOPHER BRIAN, B.S. (Florida) 1995. Interaction of Femtosecond Laser Pulses with Transparent Materials. (Mazur)

SPRADLIN, MARCUS BENJAMIN, B.A. (Princeton) 1996. (Harvard) 1999. AdS 2 Black Holes and Soliton Moduli Spaces. (Strominger)

WU, CLAUDIA, Diplom (Hannover) 1991. (Harvard) 1995. Femtosecond Laser-Gas-Solid Interactions. (Mazur)

BOZOVIC, DOLORES, B.S. ( Stanford University ) 1995. (Harvard) 1997. Defect Formation and Electron Transport in Carbon Nanotubes. (Tinkham)

BRITTO-PACUMIO, RUTH ALEXANDRA, B.S. (MIT) 1996. (Harvard) 1998. Bound States of Supersymmetric Black Holes. (Strominger)

CACHAZO, FREDDY ALEXANDER, B.S. (Simon Bolivar University) 1996. Dualities in Field Theory from Geometric Transitions in String Theory. (Vafa)

CHOU, YI, B.S. ( National Tsing Hua University ) 1988. ( National Tsing Hua University ) 1990. Developments of EXITE2 and Timing Analysis of Ultra-Compact X-ray Binaries. (Papaliolios/Grindlay)

COLDWELL, CHARLES MICHAEL, A.B. (Harvard) 1992. A Search for Interstellar Communications at Optical Wavelengths. (Horowitz)

DUTTON, ZACHARY JOHN, B.A. (University of California Berkeley) 1996. (Harvard) 2002. Ultra-slow Stopped, and Compressed Light in Bose-Einstein Condensates. (Hau)

FOX, DAVID CHARLES, A.B. ( Princeton ) 1991. (Harvard) 1994. The Structure of Clusters of Galaxies. (Shapiro)

GOEL, ANITA, B.S. (Stanford) 1995. Single Molecule Dynamics of Motor Enzymes Along DNA. (Herschbach/ Wilson)

HALL, CARTER, B.S. (Virginia Polytechnic Institute and State Univ.) 1996. Measurement of the isolated direct photon cross section with conversions in proton-antiproton collisions at sqrt (s) = 1.8 TeV. (Franklin)

JANZEN, PAUL HENRY, B. Sc., (University of Windsor) 1992. (Harvard) 1994. An Experiment to Measure Electron Impact Excitation of Ions that have Metastable States. (Horowitz/Kohl)

KIM, Daniel Young-Joon, AB/AM (Harvard) 1995. Properties of Inclusive B → psi Production. (Wilson/Brandenburg)

LANDHUIS, DAVID PAUL, B.S. (Stanford) 1994. (Harvard) 1997. Studies with Ultracold Metastable Hydrogen. (Gabrielse/Kleppner)

LAU, CHUN-NING, B.A. ( Chicago ) 1994. (Harvard) 1997. Quantum Phase Slips in Superconducting Nanowires . (Tinkham)

LEE, CHUNGSOK, B.A. ( University of California , Berkeley ) 1995. ( Harvard University ) 2002. Control and Manipulation of Magnetic Nanoparticles and Cold Atoms Using Micro-electromagnets. (Westervelt)

LUBENSKY, DAVID KOSLAN, A.B. ( Princeton University ) 1994. (Harvard) 1997. Theoretical Studies of Polynucleotide Biophysics. (Nelson)

MATTONI, CARLO EGON HEINRICH, A.B. ( Harvard College ) 1995. (Harvard University ) 1998. Magnetic Trapping of Ultracold Neutrons Produced Using a Monochromatic Cold Neutron Beam. (Doyle)

MCKINSEY, DANIEL NICHOLAS, B.S. (University of Michigan) 1995. (Harvard) 1998. Detecting Magnetically Trapped Neutrons: Liquid Helium As a Scintillator. (Doyle)

OZEL, FERYAL, B.S. (Columbia University) 1996. The Effects of Strong Magnetic and Gravitational Fields on Emission Properties of Neutron Stars. (Narayan)

PAUTOT, SOPHIE, B.S. (University of Bordeaux I and II) 1995. (University of Bordeaux I and II) 1996. Lipids behavior at dodecane-water interface. (Weitz)

PRASAD, VIKRAM, B. Tech. (Indian Institute of Technology) 1996. ( University of Pennsylvania ) 1999. Weakly interacting colloid-polymer mixtures. (Weitz)

SALWEN, NATHAN KALMAN, A.B. (Harvard) 1994. Non-perturbative Methods in Modal Field Theory. (Coleman)

SCHWARZ, JENNIFER MARIE, B.S., B.A. (University of Maryland) 1994. Depinning with Elastic Waves: Criticality, Hysteresis, and Even Pseudo-Hysteresis. (Fisher)

SHAW, SCOT ELMER JAMES, B.A. (Lawrence University) 1998. Propagation in Smooth Random Potentials. [PDF: ~7.44MB] ( Heller)

SQUIRES, TODD MICHAEL, B.S. (UCLA) 1995. Hydrodynamics and Electrokinetics in Colloidal and Microfluidic Systems. (Fisher/Brenner)

VOLOVICH, ANASTASIA, A.M. (Moscow State) 1998. Holography for Coset Spaces and Noncommutative Solitions. (Strominger)

WEINSTEIN, JONATHAN DAVID, B.S. (Caltech) 1995. (Harvard) 1998. Magnetic Trapping of Atomic Chromium and Molecular Calcium Monohydride. (Doyle)

WONG, GLENN PATRICK, B.S. (Stanford) 1993. (Harvard) 1995. Nuclear Magnetic Resonance Experiments Using Laser-Polarized Noble Gas . (Shapiro)

YESLEY, PETER SPOOR, B.S. (MIT) 1995. The Road to Antihydrogen. (Gabrielse)

*YOUNKIN, REBECCA JANE, A.B. ( Mt. Holyoke ) 1993. (Harvard) 1996. Surface Studies and Microstructure Fabrication Using Femtosecond. (Mazur)

ASHCOM, JONATHAN BENJAMIN, B.S. (Brown University) 1996. (Harvard) 2000. The role of focusing in the interaction of femtosecond laser pulses with transparent materials. (Mazur)

CHAN, IAN HIN-YUN , B.S. ( Sanford University ) 1994. Quantum dot circuits: single-electron switch and few-electron quantum dots . (Westervelt)

CREMERS, JACOB NICO HENDRIK JAN, B.S. (MIT) 1994. (Harvard) 2002. Pumping and Spin-Orbit Coupling in Quantum Dots. (Halperin)

deCARVALHO, ROBERT, B.S. (University of Arizona) 1996. (Harvard) 1999. Inelastic Scattering of Magnetically Trapped Atomic Chromium. (Doyle)

D’URSO, BRIAN RICHARD, B.S. (California Institute of Technology) 1998. Cooling and Self-Excitation of a One-Electron Oscillator. (Gabrielse)

FIETE, GREGORY ALAN, B.S. (Purdue University) 1997. (Harvard) 1999. Theory of Kondo Effect in Nanoscale Systems and Studies of III-V Diluated Magnetic Semiconductors. (Heller)

GABEL, CHRISTOPHER VAUGHN, A.B. (Princeton University) 1996. The speed of the flagellar rotary motor of Escherichia coli varies linearly with protonmotive force. (Berg)

GORDON, VERNITA DIANE, B.S. (Vanderbilt University) 1996. (Harvard) 2001. Measuring and Engineering Microscale Mechanical Responses and Properties of Bio-Relevant Materials. (Weitz)

HAILU, GIRMA, B.S. (Addis Ababa University). (Addis Ababa University) 1992. (Harvard) 1999. Chiral orbifold Construction of Field Theories with Extra Dimensions. (Georgi)

HEADRICK, MATTHEW PETER, B.A. (Princeton University) 1994. (Harvard) 1998. Noncummutative Solitons and Closed String Tachyons. (Minwalla)

HUMPHREY, MARC ANDREW, B.S. (Western Michigan University). 1997 (Harvard) 2000. Precision measurements with atomic hydrogen masers. (Walsworth)

LEPORE, NATASHA, B.S. (University of Montreal) Diffraction and Localization in Quantum Billiards. [Postscript: ~5.8MB] (Heller)

LEROY, BRIAN JAMES, Imaging Coherent Electron Flow Through Semiconductor Nanostructures. [PDF: ~10.17MB] (Westervelt)

LOPATNIKOVA, ANNA, B.S. (MIT) 1997. Spontaneously symmetry-broken states in the quantum Hall regime. (Halperin/Wen)

MADRAK, ROBYN LEIGH, B.A. (Cornell University) 1995 Measurement of the LambdaB Lifetime in the Decay Mode LambdaB-> Jpsi Lambda . (Franklin)

MALONEY, ALEXANDER DEWITT, Time-Dependent Backgrounds of String Theory . [PDF: ~6.73MB] (Strominger)

MAOZ, LIAT, B.S. (Hebrew University) 1995. Supersymmetric Configurations in the Rotating D1-D5 System and PP-Waves. [PDF: ~7.16 MB] (Maldacena/ Strominger)

MARINELLI, LUCA, Laurea ( University of Genova ) 1995. ( Harvard University ) 1997. Analysis of quasiparticles in the mixed state of a d-wave superconductor and NMR in pores with surface relaxation. (Halperin)

REFAEL, GIL, B.S. (Tel Aviv University) 1997. (Harvard) 2001. Randomness, Dissipation, and Quantum Fluctuations in Spin Chains and Mesoscopic Superconductor Arrays. (Fisher/Demler)

SHEN, NAN, B.A. (Rhode Island College) 1996. Photodisruption in biological tissues using femtosecond laser pulses . (Mazur)

TSERKOVNYAK, YAROSLAV, (University of British Columbia) 1999. (Harvard) 2001. Spin and Charge Transfer in Selected Nanostructures. [PDF: ~6.96MB] (Halperin)

VALENTINE, MEGAN THERESA, B.S. (Leigh University) 1997. (University of Pennsylvania) 1999. Mechanical and Microstructural Properties of Biological Materials . [PDF: ~3.5 MB] (Weitz)

VANICEK, JIRI JOSEPH LADISLAV, A.B. (Harvard College). (Harvard) 2000. Uniform semiclassical approximations and their applications . [PDF: 936 KB] (Heller)

WIJNHOLT, MARTIJN PAUL, B.S. (University of Warwick) 1996. Investigations in the physics of solitons in string theory. (Vafa)

ZABOW, GARY, B.S. (University of Cape Town) 1994. Charged-particle optics for neutral particles. (Prentiss)

ZIELINSKI, LUKASZ JOZEF, B.S. (Stanford University) 1997. Restriction and inhomogeneous magnetic fields in the nuclear magnetic resonance study of diffusion. (Halperin/Sen)

ABRAHAM, MATHEW CHEERAN, B.S. (Haverford College) 1997 (Harvard University) 2000. Hot Electron Transpoort and Current Sensing. (Westervelt)

BOWDEN, NATHANIEL SEAN, B.S., M.S. (University of Auckland) 1996. Production of Cold Antihydrogen During the Positron Cooling of Antiprotons. (Gabrielse)

CHANG, SPENCER, B.S. (Stanford University) 1999. (Harvard) 2001. Topics in Little Higgs Physics . [PDF: 467 KB] (Georgi)

DZHOSYUK, SERGEI N., B.S.(Moscow Institute of Physics and Technology)1995.(Moscow Institute of Physics and Technology)1997. M agnetic trapping of neutrons for measurement of the neutron lifetime. (Doyle)

EGOROV, DMITRO MIKHAILOVICH, B.S. (Moscow Institute of Physics and Technology) 1998. Buffer-Gas Cooling of Diatomic Molecules . [PDF: ~4.1 MB] (Doyle)

FIETE, ILA RANI, B.S. (University of Michigan) 1997. (Harvard University) 2000. Learning and coding in biological neural networks . (Fisher/Seung)

GARDEL, MARGARET LISE, B.A. (Brown University) 1998. (Harvard University) 2003. Elasticity of F-actin Networks. (Weitz)

HSU, MING F., A.B. ( Princeton University) 1999. Charged Colloidal Particles in Non-polar Solvents and Self-assembled Colloidal Model Systems . (Weitz)

KING, GAVIN MCLEAN, B.S. (Bates College) 1997 (Dartmouth college) 2001. Probing the Longitudinal Resolution of a Solid State nanopore Microscope with Nanotubes. (Golovchenko)

MANLEY, SULIANA, B.A.(Rice University) 1997. (Harvard University) 2001. Mechanical stability of fractal colloid gels. (Weitz)

MICHNIAK,JR.,ROBERT ALLEN, B.S. (University of Michigan) 1997. (Harvard University) 2001. Enhanced Buffer Gas Loading: Cooling and Trapping of Atoms with Low Effective Magnetic Moments. (Doyle)

MODY, AREEZ MINOO, B.S. (Caltech) 1994. Thermodynamics of ultracold singly charged particles. (Heller)

ODOM, BRIAN CARL, B.S. (Stanford University) 1995. (Harvard University) 1999. Measurement of the Electron g-Factor in a Sub-Kelvin Cylindrical Cavity . (Gabrielse)

OXLEY, PAUL KEVIN, B.A. (Oxford University) 1994. Production of Slow Antihydrogen from Cold Antimatter Plasmas . [PDF: ~5.9 MB](Gabrielse)

ROESER, CHRISTOPHER ALLAN DEWALD, B.A. (University of Chicago) 1998. Ultrafast Dynamics and Optical Control of Coherent Phonons in Tellurium. (Mazur)

SHPYRKO, OLEG GRIGORY, B.S. (Moscow Institute of Physics and Technology) 1995. Experimental X-Ray Studies of Liquid Surfaces. (Pershan)

SON, JOHN SANG WON, B.A. (Columbia University) 1996. Superstring Theory in AdS_3 and Plane Waves . [PDF: ~450 KB](Minwalla)

ZELEVINSKY, TANYA, S.B. (MIT) 1999. (Harvard University) 2001. Helium 2^3 P Fine Structure Measurement in a Discharge Cell. (Gabrielse)

ZUMBÜHL, DOMINIK MAX, Diploma, M.S. (Swiss Federal Institute of Technology), 1998. Coherence and Spin in GaAs Quantum Dots . [PDF: ~2.7 MB] (Marcus)

ANDRÉ, AXEL PHILIPPE, M.S. (Imperial College) 1997. (HarvardUniversity) 1999. Nonclassical States of Light and Atomic Ensembles: Generation and New Applications. (Lukin)

BIERCUK, MICHAEL JORDAN, Local Gate Control in Carbon Nanotube Quantum Devices. (Marcus)

CHEN, HAOYU HENRY, (University Maryland) 1998. (Harvard University) 2000. Surfaces in Solid Dynamics and Fluid Statics . [PDF: ~2.5 MB] (Brenner)

CONRAD, JACINTA CARMEL, S.B. (University of Chicago) 1999. ( Harvard University) 2002. Mechanical Response and Dynamic Arrest in Colloidal Glasses and Gels. (Weitz)

DASGUPTA, BIVASH R., B.S.C. (Presidency College) 1995. (Indian Institute of Technology) 1997. Microrheology and Dynamic Light Scattering Studies of Polymer Solutions. (Weitz)

HANCOX, CINDY IRENE, B.A. (University of California, Berkeley) 1997. ( Harvard University) 2002. Magnetic trapping of transition-metal and rare-earth atoms using buffer-gas loading. (Doyle)

HOUCK, ANDREW A., B.S.E. (Princeton University) 2000. Novel Techniques Towards Nuclear Spin Detection. (Marcus/Chuang)

LEE, HAK-HO, B.S. (Seoul National University) 1998. Microelectronic/Microfluidic Hybrid System for the Manipulation of Biological Cells. (Westervelt).

NEITZKE, ANDREW M., A.B. (Princeton University) 1998. Toward a Nonperturbative Topological String. (Vafa)

PODOLSKY, DANIEL, B.S. ( Stanford University) 1998. (Harvard University) 2000. Interplay of Magnetism and Superconductivity in Strongly Correlated Electron Systems. (Demler)

RAPPOCCIO, SALVATORE ROCCO, B.A. (Boston University ) 2000. Measurement of the ttbar Production Cross Section in ppbar Collisions at sqrt (s) = 1.96 TeV. (Foland)

SPECK, ANDREW J., (Williams College) 2000. (Harvard) 2002. Two Techniques Produce Slow Antihydrogen . [PDF: ~9.2 MB] (Gabrielse)

TEE, SHANG YOU, B.S. ( Columbia University) 1995. (Stevens Institute of Technology) 1997. Velocity Fluctuations in Sedimentation and Fluidized Beds. (Weitz)

THOMPSON, DAVID MATTOON, (Yale) 1999 B.S./M.S. Holography and Related Topics in String Theory . [PDF: ~440 KB] (Strominger)

ZHU, CHENG, B.S. ( Tsinghua University) 1996. (Chinese Science and Technology University) 1997. Gas phase atomic and molecular process . (Lukin/Dalgarno)

BABICH, DANIEL MICHAEL, A.B. ( Princeton University) 2002. ( Harvard University) 2005. Cosmological Non-Gaussianity and Reionization . (Loeb)

BARNETT, RYAN LEE, B.S. ( Ohio State University) 2000. ( Harvard University) 2002. Studies of Strongly correlated Systems: From First Principles Computations to Effective Hamiltonians and Novel Quantum Phases. (Demler)

BOWLES, ANITA MARIE, B.S. ( University of Colorado) 1996. ( Harvard University) 1998. Stress Evolution in Thin Films of a Polymer . (Weitz/Spaepen)

CHIJIOKE, AKOBUIJE DOUGLAS EZIANI, B.S.E. ( Duke University) 1996. (Massachusetts Institute of Technology) 1998. Infrared absorption of compressed hydrogen deuteride and calibration of the ruby pressure gauge . [PDF: ~2.6 MB](Silvera)

CYRIER, MICHELLE CHRISTINE, B.S. ( University of California , Berkeley) 2000. Physics From Geometry: Non-Kahler Compactifications, Black Rings and dS/CFT. (Strominger)

DESAI, MICHAEL MANISH, B.A. ( Princeton University ) 1999. ( University of Cambridge ) 2000. Evolution in Large Asexual Populations. (Murray/Fisher)

EISAMAN, MATTHEW D, A.B. (Princeton) 2000. (Harvard University) 2004. Generation, Storage and Retrieval of Nonclassical States of Light Using Atomic Ensembles . [PDF: ~7 MB] (Lukin)

HOLLOWAY, AYANA TAMU, A.B. ( Princeton University) 1998. The First Direct Limit on the t Quark Lifetime. ( Franklin)

HOWARD, ANDREW WILLIAM, S.B. (Massachusetts Institute of Technology) 1998. (Harvard University) 2001. Astronomical Searches for Nanosecond Optical Pulses. (Horowitz)

HUANG, JIAN, BS (Jilin University, P.R.China)1998. Theories of Imaging Electrons in Nanostructures . [PDF: ~8.4 MB] (Heller)

JONES, GREGORY CHAPMAN, B.S. (University of Missouri, Columbia) 2001. Time-dependent solutions in gravity . (Strominger)

KILIC, CAN, B.S. ( Bogazici University) 2000. Naturalness of Unknown Physics: Theoretical Models and Experimental Signatures. (Arkani-Hamed)

LAKADAMYALI, MELIKE, B.S. ( University of Texas , Austin ) 2001. Real-Time Imaging of Viral Infection and Intracellular Transport in Live Cells. (Zhuang)

MAHBUBANI, RAKHI, MSci (University of Bristol) 2000. Beyond the Standard Model: The Pragmatic Approach to the Gauge Hierarchy Problem . [PDF: ~1.5 MB] (Arkani-Hamed)

MARSANO, JOSEPH DANIEL, B.S. (University of Michigan) 2001. (Harvard University) 2004. The Phase Structure of Yang-Mills Theories and their Gravity Duals. (Minwalla)

NGUYEN, SCOTT VINH, B.S. (University of Texan, Austin) 2000. Buffer gas loading and evaporative cooling in the multi-partial-wave regeime. (Doyle)

PAPADODIMAS, KYRIAKOS, B.A. ( University of Athens ) 2000. Phase Transitions in Large N Gauge Theories and String Theory Duals. (Minwalla)

PARROTT, ROBERT ELLIS, B.A. (Dartmouth College) 1997. (Dartmouth College) 1999. Topics in Electron Dynamics in Moderate Magnetic Fields . (Heller)

POTOK, RONALD MICHAEL, B.S. ( University of Texas Austin) 2000. Probing Many Body Effects in Semiconductor Nanostructures. (Goldhaber-Gordon/Marcus)

RUST, MICHAEL JOSEPH, B.S. ( Harvey Mudd College ). Fluorescence Techniques for Single Virus Particle Tracking and Sub-Diffraction Limit Imaging. (Zhuang)

SAGE, JENNIFER NICOLE FUES, B.A. ( Washington University ) 1997. ( Harvard University ) 2000. Measurements of Lateral Boron Diffusion in Silicon and Stress Effects on Epitaxial Growth . (Aziz/Kaxiras)

TAYLOR, JACOB MASON, A.B. ( Harvard College ) 2000. Hyperfine Interactions and Quantum Information Processing in Quantum Dots. (Lukin)

THALER, JESSE KEMPNER, S.B. (Brown University). ( Harvard University) 2004. Symmetry Breaking at the Energy Frontier . (Arkani-Hamed)

THAMBYAHPILLAI, SHIYAMALA NAYAGI, M.S. (Imperial College) 1999. Brane Worlds and Deconstruction. (Randall)

VAISHNAV, JAY Y., B.S. (University of Maryland) 2000. ( Harvard University) 2002. Topics in Low Energy Quantum Scattering Theory. [PDF: ~3.8 MB] (Heller)

VITELLI, VINCENZO, B.S. (Imperial College) 2000. Crystals , Liquid Crystals and Superfluid Helium on Curved Surfaces. (Nelson)

WALKER, DEVIN GEORGE EDWARD, B.S. (Hampton University) 1998. ( Harvard University ) 2001. Theories on the Origin of Mass and Dark Matter. (Arkani-Hamed/Georgi)

WHITE, OLIVIA LAWRENCE, B.S. ( Stanford University ) 1997. Towards Real Spin Glasses: Ground States and Dynamics. (Fisher)

YIN, XI, B.S. (University of Science and Technology of China) 2001. Black Holes, Anti de Sitter Space, and Topological Strings. (Strominger)

YANG, LIANG, B.S. (Yale University) 1999. ( Harvard University) 2002. Towards Precision Measurement of the Neutron Lifetime using Magnetically Trapped Neutrons. (Doyle)

YAVIN, ITAY, B. Sc. (York University, Ontario) 2002. Spin Determination at the Large Hadron Collider. [PDF: ~662 KB] (Arkani-Hamed)

CHILDRESS, LILIAN ISABEL, B.A. (Harvard College) 2001. Coherent manipulation of single quantum systems in the solid state . (Lukin)

CLARK, DAMON ALISTAIR Biophysical Analysis of Thermostatic Behavior in C. elegans . (Samuel)

ERNEBJERG, MORTEN, MPhys (University of Oxford) 2002. Field Theory Methods in Two-Dimensional and Heterotic String Theories . (Strominger)

FARKAS, DANIEL MARTIN, B.S. (Yale University) 2000. An Optical Reference and Frequency Comb for Improved Spectroscopy of Helium . (Gabrielse)

GINSBERG, NAOMI SHAUNA, B.A. (University of Toronto) 2000. (Harvard University) 2002. Manipulations with spatially compressed slow light pulses in Bose-Einstein condensates. (Hau)

HOFFMAN, LAUREN K., B.S. (California Institute of Technology) 2002. Orbital Dynamics in Galaxy Mergers . (Loeb)

HUANG, LISA LI FANG, B.S. (UCLA) 1999. Black Hole Attractors and Gauge Theories . (Strominger)

HUNT, THOMAS PETER, B.S. (Stanford University) 2000. Integrated Circuit / Microfluidic Chips for Dielectric Manipulation . (Westervelt)

IMAMBEKOV, ADILET, B.S. (Moscow Institute of Physics and Technology) 2002. Strongly Correlated Phenomena with Ultracold Atomic Gases . (Demler)

JAFFERIS, DANIEL LOUIS, B.S. (Yale) 2001. Topological String Theory from D-Brane Bound States . (Vafa)

JENKS, ROBERT A., B.A. (Williams College) 1998. Mechanical and neural representations of tactile information in the awake behaving rat somatosensory system . (Stanley/Weitz)

LEBEDEV, ANDRE, B.S. (University of Virginia) 1999. Ratio of Pion Kaon Production in Proton Carbon Interactions . (Feldman)

LIU, JIAYU, B.S. (Nanjing University of China) 2002. (Harvard) 2004. Microscopic origin of the elasticity of F-actin networks . (Weitz)

MATHEY, LUDWIG GUENTER, Vordiplom (University of Heidelberg) 1998. Quantum phases of low-dimensional ultra-cold atom systems. (Castro-Neto/Halperin)

MAXWELL, STEPHEN EDWARD Buffer Gas Cooled Atoms and Molecules: Production, Collisional Studies, and Applications. (Doyle)

MO, YINA, B.S. (University of Science and Technology China) 2002. Theoretical Studies of Growth Processes and Electronic Properties of Nanostructures on Surfaces. (Kaxiras)

PARUCHURI, SRINIVAS S., B. S. (Cornell) 2000. (Harvard University) 2002. Deformations of Free Jets . (Brenner//Weitz)

QIAN, JIANG Localization in a Finite Inhomogeneous Quantum Wire and Diffusion through Random Spheres with Partially Absorbing Surfaces. (Halperin)

RITTER, WILLIAM GORDON, B.A. (University of Chicago) 1999. Euclidean Quantum Field Theory: Curved Spacetimes and Gauge Fields. (Jaffe)

SARAIKIN, KIRILL ANATOLYEVICH, B.S. (Moscow Institute for Physics and Technology) 1999. Black Holes, Entropy Functionals, and Topological Strings. (Vafa)

SCHULZ, ALEXIA EIRINN, B.A. (Boston University ) 1998. (Harvard University) 2000. Astrophysical Probes of Dark Energy. (White/Huth)

SCHUSTER, PHILIP CHRISTIAN, S.B. (Massachusetts Institute of Technology) 2003. ( Harvard University ) 2006. Uncovering the New Standard Model at the LHC . (Arkani-Hamed)

SEUN, SIN MAN, B.A. (Smith College) 2000. B.E. (Dartmouth College) 2000. Measurement of p-K Ratios from the NuMI Target . (Feldman)

SHERMAN, DANIEL JOSEPH, B.A. (University of Pennsylvania ) 2001. Measurement of the Top Quark Pair Production Cross Section with 1.12 fb -1 of pp Collisions at sqrt (s) = 1.96 TeV. ( Franklin )

SIMONS, AARON, B.S. (California Institute of Technology) 2002. Black Hole Superconformal Quantum Mechanics. (Strominger)

SLOWE, CHRISTOPHER BRIAN, AB/AM (Harvard University). Experiments and Simulations in Cooling and Trapping of a High Flux Rubidium Beam. (Hau)

STRIEHL, PIERRE SEBASTIAN, Diploma (University of Heidelberg) 2004. A high-flux cold-atom source for area-enclosing atom interferometry. (Prentiss)

TORO, NATALIA, S.B. (Massachusetts Institute of Technology) 2003. Fundamental Physics at the Threshold of Discovery . (Arkani-Hamed)

WISSNER-GROSS, ALEXANDER DAVID, S.B. (Massachusetts Institute of Technology) 2003. (Harvard University ) 2004. Physically Programmable Surfaces. (Kaxiras)

WONG, WESLEY PHILIP, B.S. (University of British Columbia) 1999. Exploring single-molecule interactions through 3D optical trapping and tracking: from thermal noise to protein refolding . (Evans/Nelson)

ZAW, INGYIN, B.A. (Harvard College) 2001. (Harvard University) 2003. Search for the Flavor Changing Neutral Current Decay t → qZ in pp Collisions at √s = 1.96 TeV. (Franklin)

BRAHMS, NATHANIEL CHARLES, Sc.B. (Brown University) 2001. Trapping of 1 μ β Atoms Using Buffer Gas Loading . (Doyle, Greytak)

BURBANK, KENDRA S., B.A. (Bryn Mawr College) 2000. (Harvard University) 2004. Self-organization mechanisms in the assembly and maintenance of bipolar spindles. (Fisher/Mitchison)

CAMPBELL, WESLEY C., B.S. (Trinity University) 2001. Magnetic Trapping of Imidogen Molecules . (Doyle)

CHAISANGUANTHUM, KRIS SOMBOON, B.S. (Harvard University ) 2001. An Enquiry Concerning Charmless Semileptonic Decays of Bottom Mesons . (Morii)

CHANG, DARRICK, B.S. (Stanford University) 2001. Controlling atom-photon interactions in nano-structured media. (Lukin)

CHOU, JOHN PAUL, A.B. (Princeton University) 2002. (Harvard University) 2006. Production Cross Section Measurement using Soft Electron Tagging in pp Collisions at √s = 1.96 TeV . (Franklin)

DEL MAESTRO, ADRIAN GIUSEPPE, B.S. (University of Waterloo) 2002, (University of Waterloo) 2003. The Superconductor-Metal Quantum Phase Transition in Ultra-Narrow Wires . (Sachdev)

DI CARLO, LEONARDO, B.S. (Stanford University) 1999. (Stanford University) 2000. Mesocopic Electronics Beyond DC Transport . (Marcus)

DUNKEL, EMILY REBECCA, B.S. (University of California Los Angeles) 2001. Quantum Phenomena in Condensed Phase Systems . (Sachdev/Coker)

FINKLER, ILYA GRIGORYEVICH, B.S. (Ohio State University) 2001. Nonlinear Phenomena in Two-Dimensional and Quasi-Two-Dimensional Electron Systems. (Halperin)

FITZPATRICK, ANDREW LIAM, B.S. (University of Chicago) 2004. (Harvard University) 2005. Broken Symmetries and Signatures . (Randall)

GARG, ARTI, A.B., B.S. (Stanford University) 2000. (Stanford University) 2001. (University of Washington) 2002. Microlensing Candidate Selection and Detection Efficiency for the Super MACHO Dark Matter Search . (Stubbs)

GERSHOW, MARC HERMAN, B.S. (Stanford University) 2001. Trapping Single Molecules with a Solid State Nanopore . (Golovchenko)

GRANT, LARS, B.S. (McGill University) 2001. Aspects of Quantization in AdS/CFT . (Vafa/Minwalla)

GUICA, MONICA MARIA, B.A. (University of Chicago) 2003. Supersymmetric Attractors, Topological Strings, and the M5-Brane CFT . (Strominger)

HANNEKE, DAVID ANDREW, B.S. (Case Western) 2001. (Harvard University) 2003. Cavity Control in a Single-Electron Quantum Cyclotron: An Improved Measurement of the Electron Magnetic Moment. (Gabrielse)

HATCH, KRISTI RENEE, B.S. (Brigham Young University) 2004 Probing the mechanical stability of DNA by unzipping and rezipping the DNA at constant force. (Prentiss)

HOHLFELD, EVAN BENJAMIN, B.S. (Stanford University) 2001. Creasing, Point-bifurcations, and the Spontaneous Breakdown of Scale-invariance . (Weitz/Mahadevan)

KATIFORI, ELENI, Ptichion (University of Athens) 2002. (Harvard University) 2004. Vortices, rings and pollen grains: Elasticity and statistical physics in soft matter . (Nelson)

LAPAN, JOSHUA MICHAEL, B.S. (Massachusetts Institute of Technology) 2002. (Harvard University) 2006. Topics in Two-Dimensional Field Theory and Heterotic String Theory . (Strominger)

LE SAGE, DAVID ANTHONY, B.S. (University of California Berkeley) 2002. First Antihydrogen Production within a Combined Penning-Ioffe Trap . (Gabrielse)

LI, WEI, B.S. (Peking University) 1999. (Peking University) 2002. Gauge/Gravity Correspondence and Black Hole Attractors in Various Dimensions . (Strominger)

LU, PETER JAMES, B.A. (Princeton University) 2000. (Harvard University) 2002. Gelation and Phase Separation of Attractive Colloids . (Weitz)

MUNDAY, JEREMY NATHAN, B.S. (Middle Tennessee State University) 2003. (Harvard University) 2005. Attractive, repulsive, and rotational QED forces: experiments and calculations . (Hau/Capasso)

RAJU, SUVRAT, B.S. (St. Stephen’s College) 2002. (Harvard University) 2003. Supersymmetric Partition Functions in the AdS/CFT Conjecture . (Arkani-Hamed/Denef/Minwalla)

RISTROPH, TRYGVE GIBBENS, B.S. (University of Texas at Austin) 1999. Capture and Ionization Detection of Laser-Cooled Rubidium Atoms with a Charged Suspended Carbon Nanotube . (Hau)

SVACHA, GEOFFRY THOMAS, B.S. (University of Michigan) 2002. Nanoscale nonlinear optics using silica nanowires . (Mazur)

TURNER, ARI M., B.A. (Princeton University) 2000. Vortices Vacate Vales and other Singular Tales . (Demler)

BAUMGART, MATTHEW TODD, B.S. (University of Chicago) 2002. The Use of Effective Variables in High Energy Physics . (Georgi/Arkani-Hamed)

BOEHM, JOSHUA ADAM ALPERN, B.S.E. (Case Western Reserve University) 2003. (Harvard University) 2005. A Measurement of Electron Neutrino Appearance with the MINOS Experimen t. (Feldman)

CHEUNG, CLIFFORD WAYNE, B.S. (Yale University) 2004. (Harvard University) 2006. From the Action to the S-Matrix . (Georgi/Arkani-Hamed)

DORET, STEPHEN CHARLES B.A. (Williams College) 2002, A.M. (Harvard University) 2006. A buffer-gas cooled Bose-Einstein condensate . (Doyle)

FALK, ABRAM LOCKHART, B.A. (Swarthmore College) 2003. (Harvard University) 2004. Electrical Plasmon Detection and Phase Transitions in Nanowires . (Park)

HAFEZI, MOHAMMAD, (Sharif University of Technology, Tehran - Ecole Polytechnique, Paris) 2003. (Harvard University) 2005, Strongly interacting systems in AMO physics . (Lukin)

HECKMAN, JONATHAN JACOB, A.B. (Princeton University) 2004. (Harvard University) 2005 F-theory Approach to Particle Physics . (Vafa)

HICKEN, MALCOLM STUART, B.S. (Brigham Young University) 1999. (Harvard University) 2001. Doubling the Nearby Supernova Type Ia Sample . (Stubbs/Kirshner)

HOHENSEE, MICHAEL ANDREW, B.A. (New York University) 2002. (Harvard University) 2004. Testing Fundamental Lorentz Symmetries of Light . (Walsworth)

JIANG, LIANG, B.S. (California Institute of Technology) 2004. T owards Scalable Quantum Communication and Computation: Novel Approaches and Realizations . (Lukin)

KAPLAN, JARED DANIEL, B.S. (Stanford University) 2005. Aspects of Holography . (Georgi/Arkani-Hamed)

KLEIN, MASON JOSEPH, B.S. (Calvin College) 2002. Slow and Stored Light in Atomic Vapor Cells . (Walsworth)

KRICH, JACOB JONATHAN, B.A. (Swarthmore College) 2000, MMath (Oxford University) 2003. (Harvard University) 2004. Electron and Nuclear Spins in Semiconductor Quantum Dots . (Halperin)

LAHIRI, SUBHANEIL, M.A. (Oxford University) 2003. Black holes from fluid mechanics. (Yin/Minwalla)

LIN, YI-CHIA, B.S. (National Taiwan Normal University) 1999. (National Tsing Hua University) 2001. Elasticity of Biopolymer Networks. (Weitz)

LUO, LINJIAO, B.S. (University of Science and Technology China) 2003. Thermotactic behavior in C. elegans and Drosophila larvae. (Samuel)

PADI, MEGHA, B.S. (Massachusetts Institute of Technology) 2003. A Black Hole Quartet: New Solutions and Applications to String Theory. (Strominger)

PASTRAS, GEORGIOS, DIPLOMA (University of Patras) 2002. (Harvard University) 2004. Thermal Field Theory Applications in Modern Aspects of High Energy Physics. (Denef/Arkani-Hamed)

PEPPER, RACHEL E., B.S. (Cambridge) 2004. Splashing, Feeding, Contracting: Drop impact and fluid dynamics of Vorticella (Stone)

SHAFEE, REBECCA, B.S. (California Institute of Technology) 2002. (Harvard University) 2004. Measuring Black Hole Spin. (Narayan/McClintock)

WANG, CHRISTINE YI-TING, B.S. (National Taiwan University) 2002. (Harvard University) 2004. Multiode dynamics in Quantum Cascade Lasers: from coherent instability to mode locking. (Hoffman/Capasso)

ZHANG, YIMING, B.S. (Peking University) 2003. (Harvard University) 2006. Waves, Particles, and Interactions in Reduced Dimensions . (Marcus)

BARTHEL, CHRISTIAN, Diploma (University of Kaiserslautern) 2005. Control and Fast Measurement of Spin Qubits . (Marcus)

CAVANAUGH, STEVEN, B.S. (Rutgers College) 2005. (Harvard University) 2006. A Measurement of Electron Neutrino Appearance in the MINOS Experiment after Four Years of Data . (Feldman)

CHERNG, ROBERT, WEN-CHIEH, B.S. (Massachusetts Institute of Technology) 2004. Non-Equilibrium Dynamics and Novel Quantum Phases of Multicomponent Ultracold Atoms . (Demler)

FOLETTI, SANDRA ELISABETTA, Diploma (Federal Institute of Technology Zurich) 2004. Manipulation and Coherence of a Two-Electron Logical Spin Qubit Using GaAs Double Quantum Dots . (Yacoby)

GIRASH, JOHN ANDREW, B.S. (University of Western Ontario) 1990. (University of Western Ontario) 1993. A Fokker-Planck Study of Dense Rotating Stellar Clusters . (Stubbs/Field)

GOODSELL, ANNE LAUREL, B.A. (Bryn Mawr College) 2002. (Harvard University) 2004. Capture of Laser-Cooled Atoms with a Carbon Nanotube . (Hau)

GORSHKOV, ALEXEY VYACHESLAVOVICH, A.B. (Harvard College) 2004. (Harvard University) 2006. Novel Systems and Methods for Quantum Communication, Quantum Computation, and Quantum Simulation . (Lukin)

GUISE, NICHOLAS DAMIEN SUN-WO, B.S. (California Institute of Technology) 2003. Spin-Flip Resolution Achieved with a One-Proton Self-Excited Oscillator. (Gabrielse)

HARTMAN, THOMAS EDWARD, A.B. (Princeton University) 2004. Extreme Black Hole Holography. (Strominger)

HIGH, FREDRICK WILLIAM, B.A. (University of California Berkeley) 2004. The Dawn of Wide-Field Sunyaev-Zel’dovich Cluster Surveys: Efficient Optical Follow-Up. (Stubbs)

HOOGERHEIDE, DAVID PAUL, B.S. (Western Michigan University) 2004. Stochastic Processes in Solid State Nanoporers. (Golovchenko)

HUMMON, MATTHEW TAYLOR, B.A. (Amherst College) 2002, (Harvard University) 2005. Magnetic trapping of atomic nitrogen and cotrapping of NH. (Doyle)

KATS, YEVGENY, B.S. (Bar-Ilan University) 2003. (Bar-Ilan University) 2005. Physics of Conformal Field Theories. (Georgi/Arkani-Hamed)

KOROLEV, KIRILL SERGEEVICH, B.S. (Moscow Institute of Physics and Technology) 2004. Statistical Physics of Topological Emulsions and Expanding Populations. (Nelson)

LAIRD, EDWARD ALEXANDER, M.Phys (University of Oxford) 2002. (Harvard University) 2005. Electrical Control of Quantum Dot Spin Qubits . (Marcus)

LAROCHELLE, PHILIPPE, B.S. (Massachusetts Institute of Technology) 2003. Machines and Methods for Trapping Antihydrogen. (Gabrielse)

LI, GENE-WEI, B.S. (National Tsinghua University) 2004. Single-Molecule Spatiotemporal Dynamics in Living Bacteria. (Nelson/Xie)

MAZE RIOS, JERONIMO, B.S. (Pont Catholic University), 2002. (Pont Catholic University) 2004. Quantum Manipulation of Nitrogen-Vacancy Centers in Diamond: from Basic Properties to Applications. (Lukin)

PATTERSON, DAVID, A.B. (Harvard College) 1997. Buffer Gas Cooled Beams and Cold Molecular Collisions. (Doyle)

PENG, AMY WAN-CHIH, B.Sc. (University of Auckland), (Australian National University) 2005. Optical Lattices with Quantum Gas Microscope . (Greiner)

QI, YANG, B.S. (Tsinghua University) 2005. Spin and Charge Fluctuations in Strongly Correlated Systems . (Sachdev)

ROJAS, ENRIQUE ROBERTSON, B.A. (University of Pennsylvania) 2003. The Physics of Tip-Growing Cells. (Nelson/Dumais)

SEO, JIHYE, B.S. (Korea Adv. Inst. of Science & Technology) 2003. (Harvard University) 2010. D-Branes, Supersymmetry Breaking, and Neutrinos . (Vafa)

SIMON, JONATHAN, B.S. (California Institute of Technology) 2004. Cavity QED with Atomic Ensembles. (Lukin/Vuletic)

SLATYER, TRACY ROBYN, Ph.B. (Australian National University) 2005. (Harvard University) 2008. Signatures of a New Force in the Dark Matter Sector. (Finkbeiner)

TAFVIZI, ANAHITA, B.S. (Sharif University of Technology) 2004. Single-Molecule and Computational Studies of Protein-DNA Interactions. (Cohen/Mirny/van Oijen)

WINKLER, MARK THOMAS, B.S.E. (Case Western Reserve) 2004. Non-Equilibrium Chalcogen Concentrations in Silicon: Physical Structure, Electronic Transport, and Photovoltaic Potential. (Mazur)

ANNINOS, DIONYSIOS Theodoros,B.A. (Cornell University) 2006, (Harvard University) 2008. Classical and Quantum Symmetries of de Sitter Space . (Strominger) >

BAKR, WASEEM S., B.S. (Massachusetts Institute of Technology) 2005. Microscopic studies of quantum phase transitions in optical lattices . (Greiner)

BARAK, GILAD, B.S. (Hebrew University) 2000, (Tel Aviv University) 2006. Momentum resolved tunneling study of interaction effects in ID electron systems .(Yacoby)

BARANDES, JACOB AARON, B.A. (ColumbiaUniversity) 2004. Exploring Supergravity Landscapes . (Denef)

BISWAS, RUDRO RANA, B.S. (Calcutta University) 2003, (Harvard University) 2011. Explorations in Dirac Fermions and Spin Liquids . (Sachdev)

CHEN, PEIQIU, B.S. (University of Science and Technology China) 2004, (Harvard University) 2005. Molecular evolution and thermal adaptation . (Nelson/Shakhnovich)

FREUDIGER, CHRISTIAN WILHELM, Diploma (Technische Universitat of München) 2005, (Harvard University) 2007. Stimulated Raman Scattering (SRS) Microscopy . (Zhuang/Xie)

GALLICCHIO, JASON RICHARD, B.S. (University of Illinois at Urbana Champaign) 1999, (University of Illinois at Urbana Champaign) 2001. A Multivariate Approach to Jet Substructure and Jet Superstructure . (Schwartz)

GLENDAY, ALEXANDER, B.A. (Williams College) 2002. Progress in Tests of Fundamental Physics Using a 3He and 129Xe Zeeman Maser . (Stubbs/Walsworth)

GOLDMAN, JOSHUA DAVID, A.B. (Cornell University) 2002, (University of Cambridge) 2003, (Imperial College London) 2004. Planar Penning Traps with Anharmonicity Compensation for Single-Electron Qubits. (Gabrielse)

HUH, YEJIN, B.S. (Yale University) 2006, (Harvard University) 2008. Quantum Phase Transitions in d-wave Superconductors and Antiferromagnetic Kagome Lattices . (Sachdev)

KASHIF, LASHKAR, B.S. (Yale University) 2003. Measurement of the Z boson cross-section in the dimuon channel in pp collisions at sqrt{s} = 7 TeV . (Huth)

KAZ, DAVID MARTIN, B.S. (University of Arizona) 2003, (Harvard University) 2008. Colloidal Particles and Liquid Interfaces: A Spectrum of Interactions. (Manoharan)

KOLTHAMMER, WILLIAM STEVEN, B.S. (Harvey Mudd College) 2004, (Harvard University) 2006. Antimatter Plasmas Within a Penning-Ioffe Trap . (Gabrielse)

LEE-BOEHM, CORRY LOUISE, B.S.E. (University of Colorado) 2004, (Harvard University) 2011. B0 Meson Decays to rho0 K*0, f0 K*0, and rho- K*+, Including Higher K* Resonances . (Morii)

MARTINEZ-OUTSCHOORN, VERENA INGRID, B.A. (Harvard University) 2004, (Harvard University) 2007. Measurement of the Charge Asymmetry of W Bosons Produced in pp Collisions at sqrt(s) = 7 TeV with the ATLAS Detector . (Guimaraes da Costa)

MCCONNELL, ROBERT PURYEAR, B.S. (Stanford University) 2005, (Harvard University) 2007. Laser-Controlled Charge-Exchange Production of Antihydrogen . (Gabrielse)

MCGORTY, RYAN, B.S. (University of Massachusetts) 2005, (Harvard University) 2008. Colloidal Particles at Fluid Interfaces and the Interface of Colloidal Fluids . (Manoharan)

METLITSKI, MAXIM A., B.Sc. (University of British Columbia) 2003, (University of British Columbia) 2005. Aspects of Critical Behavior of Two Dimensional Electron Systems . (Sachdev)

MOON, EUN GOOK, B.S. (Seoul National University) 2005 Superfluidity in Strongly Correlated Systems . (Sachdev)

PETERSON, COURTNEY MARIE, B.S. (Georgetown University) 2002,(University of Cambridge) 2003, (Imperial College London) 2004, (Harvard University) 2007. Testing Multi-Field Inflation . (Stubbs/Tegmark)

PIELAWA, SUSANNE, Diploma (UNIVERSITY OF ULM) 2006, (Harvard University) 2009. Metastable Phases and Dynamics of Low-DimensionalStrongly-Correlated Atomic Quantum Gases . (Sachdev)

PRASAD, SRIVAS, A.B. (Princeton University) 2005, (Harvard University) 2007. Measurement of the Cross-Section of W Bosons Produced in pp Collisions at √s=7 TeV With the ATLAS Detector . (Guimaraes da Costa)

ROMANOWSKY, MARK, B.A. (Swarthmore College) 2003. High Throughput Microfluidics for Materials Synthesis . (Weitz)

SMITH, BEN CAMPBELL, B.A. (Harvard University) 2005. Measurement of the Transverse Momentum Spectrum of W Bosons Produced at √s = 7 TeV using the ATLAS Detector . (Morii)

TANJI, HARUKA, B.S. (University of Tokyo) 2002, (University of Tokyo) 2005, (Harvard University) 2009. Few-Photon Nonlinearity with an Atomic Ensemble in an Optical Cavity . (Lukin/Vuletic)

TRODAHL, HALVAR JOSEPH, B. Sc. (Victoria University) 2005, (Harvard University) 2008. Low Temperature Scanning Probe Microscope for Imaging Nanometer Scale Electronic Devices. (Westervelt)

WILLIAMS, TESS, B.Sc. (Stanford University) 2005. Nanoscale Electronic Structure of Cuprate Superconductors Investigated with Scanning Tunneling Spectroscopy. (Hoffman)

ANDERSEN, JOSEPH, B.S. (Univ. of Queensland) 1999. Investigations of the Convectively Coupled Equatorial Waves and the Madden-Julian Oscillation. (Huth)

BREDBERG, IRENE, M.PHYS., M.Sc. (Univ. of Oxford) 2006, 2007. The Einstein and the Navier-Stokes Equations: Connecting the Two . (Strominger)

CHURCHILL, HUGH, B.A., B.M. (Oberlin College) 2006. Quantum Dots in Gated Nanowires and Nanotubes. (Marcus)

CONNOLLY, COLIN Inelastic Collisions of Atomic Antimony, Aluminum, Eerbium and Thulium Below . (Doyle)

CORDOVA, CLAY, B.A. (Columbia University) 2007. Supersymmetric Spectroscopy. (Vafa)

DILLARD, COLIN, S.B. (Massachusetts Institute of Technology) 2006. Quasiparticle Tunneling and High Bias Breakdown in the Fractional Quantum Hall Effect. (Kastner/Silvera)

DOWD, JASON, A.B. (Washington Univ.) 2006;(Harvard Univ.) 2008. Interpreting Assessments of Student Learning in the Introductory Physics Classroom and Laboratory. (Mazur)

GOLDSTEIN, GARRY Applications of Many Body Dynamics of Solid State Systems to Quantum Metrology and Computation (Chamon/Sachdev)

GUREVICH, YULIA, B.S. (Yale University) 2005. Preliminary Measurements for an Electron EDM Experiment in ThO. (Gabrielse)

KAGAN, MICHAEL, B.S. (Univ. of Michigan) 2006; (Harvard Univ.) 2008. Measurement of the W ± Z production cross section and limits on anomalous triple gauge couplings at √S = 7 TeV using the ATLAS detector. (Morii)

LIN, TONGYAN, S.B. (Massachusetts Institute of Technology) 2007; (Harvard Univ.) 2009. Signals of Particle Dark Matter. (Finkbeiner)

McCLURE, DOUGLAS, B.A. (Harvard University) 2006; (Harvard University) 2008. Interferometer-Based Studies of Quantum Hall Phenomena. (Marcus)

MAIN, ELIZABETH, B.S.(Harvey Mudd College) 2004; (Harvard Univ.) 2006. Investigating Atomic Scale Disordered Stripes in the Cuprate Superconductors with Scanning Tunneling Microscopy. (Hoffman)

MASON, DOUGLAS Toward a Design Principle in Mesoscopic Systems . (Heller/Kaxiras)

MULUNEH, MELAKU, B.A. (Swarthmore College) 2003. Soft colloids from p(NIPAm-co-AAc): packing dynamics and structure. (Weitz)

PIVONKA, ADAM Nanoscale Imaging of Phase Transitions with Scanning Force Microscopy . (Hoffman)

REAL, ESTEBAN, A.B. (Harvard University) 2002; (Harvard University) 2007. Models of visual processing by the retina. (Meister/Franklin)

RICHERME, PHILIP, S.B. (Massachusetts Institute of Technology) 2006; (Harvard University) 2008. Trapped Antihydrogen in Its Ground State. (Gabrielse)

SANTOS, LUIZ, B.S. (Univ. Fed. Do Espito Santo) 2004. Topological Properties of Interacting Fermionic Systems. (Chamon/Halperin)

SCHLAFLY, EDWARD, B.S. (Stanford University) 2007; (Harvard University) 2011. Dust in Large Optical Surveys. (Finkbeiner)

SETIAWAN, WIDAGDO, B.S. (Massachusetts Institute of Technology) 2007. Fermi Gas Microscope . (Greiner)

SHUVE, BRIAN, B.A.Sc. (University of Toronto) 2007; (Harvard University) 2011. Dark and Light: Unifying the Origins of Dark and Visible Matter. (Randall)

SIMMONS-DUFFIN, DAVID, A.B., A.M. (Harvard University) 2006. Carving Out the Space of Conformal Field Theories. (Randall)

TEMPEL, DAVID, B.A. (Hunter College) 2007. Time-dependent density functional theory for open quantum systems and quantum computation. (Aspuru-Guzik/Cohen)

VENKATCHALAM, VIVEK, S.B. (Massachusetts Institute of Technology) 2006. Single Electron Probes of Fractional Quantum Hall States. (Yacoby)

VLASSAREV, DIMITAR, B.S. (William and Mary) 2005; (Harvard University) 2007. DNA Characterization with Solid-State Nanopores and Combined Carbon Nanotube across Solid-State Nanopore Sensors . (Golovchenko)

WANG, WENQIN, B.S. (Univ. of Science and Technology of China) 2006. Structures and dynamics in live bacteria revealed by super-resolution fluorescence microscopy. (Zhuang)

WANG, YIHUA Laser-Based Angle-Resolved Photoemission Spectroscopy of Topological Insulators. (Gedik / Hoffman)

WISSNER-GROSS, ZACHARY Symmetry Breaking in Neuronal Development. (Yanik /Levine)

YONG, EE HOU, B.Sc. (Stanford University) 2003. Problems at the Nexus of Geometry and Soft Matter: Rings, Ribbons and Shells. (Mahadevan)

ANOUS, TAREK Explorations in de Sitter Space and Amorphous Black Hole Bound States in String Theory . (Strominger)

BABADI, MEHRTASH Non-Equilibrium Dynamics of Artificial Quantum Matter . (Demler)

BRUNEAUX, LUKE Multiple Unnecessary Protein Sources and Cost to Growth Rate in E.coli. (Prentiss)

CHIEN, YANG TING Jet Physics at High Energy Colliders Matthew . (Schwartz)

CHOE, HWAN SUNG Choe Modulated Nanowire Structures for Exploring New Nanoprocessor Architectures and Approaches to Biosensing. (Lieber/Cohen)

COPETE, ANTONIO BAT Slew Survey (BATSS): Slew Data Analysis for the Swift-BAT Coded Aperture Imaging Telescope . (Stubbs)

DATTA, SUJIT Getting Out of a Tight Spot: Physics of Flow Through Porous Materials . (Weitz)

DISCIACCA, JACK First Single Particle Measurements of the Proton and Antiproton Magnetic Moments . (Gabrielse)

DORR, JOSHUA Quantum Jump Spectroscopy of a Single Electron in a New and Improved Apparatus . (Gabrielse )

DZYABURA, VASILY Pathways to a Metallic Hydrogen . (Silvera)

ESPAHBODI, SAM 4d Spectra from BPS Quiver Dualities. (Vafa)

FANG, JIEPING New Methods to Create Multielectron Bubbles in Liquid Helium . (Silvera)

FELDMAN, BEN Measurements of Interaction-Driven States in Monolayer and Bilayer Graphene . (Yacoby)

FOGWELL HOOGERHEIDE, SHANNON Trapped Positrons for High-Precision Magnetic Moment Measurements . (Gabrielse)

FUNG, JEROME Measuring the 3D Dynamics of Multiple Colloidal Particles with Digital Holographic Microscopy . (Manoharan)

GULLANS, MICHAEL Controlling Atomic, Solid-State and Hybrid Systems for Quantum Information Processing. (Lukin)

JAWERTH, LOUISE MARIE The Mechanics of Fibrin Networks and their Alterations by Platelets . (Weitz)

JEANTY, LAURA Measurement of the WZ Production Cross Section in Proton-Proton Collision at √s = 7 TeV and Limits on Anomalous Triple Gauge Couplings with the ATLAS Detector . (Franklin)

JENSEN, KATHERINE Structure and Defects of Hard-Sphere Colloidal Crystals and Glasses . (Weitz)

KAHAWALA, DILANI S Topics on Hadron Collider Physics . (Randall)

KITAGAWA, TAKUYA New Phenomena in Non-Equilibrium Quantum Physics . (Demler)

KOU, ANGELA Microscopic Properties of the Fractional Quantum Hall Effect . (Halperin)

LIN, TINA Dynamics of Charged Colloids in Nonpolar Solvents . (Weitz)

MCCORMICK, ANDREW Discrete Differential Geometry and Physics of Elastic Curves . (Mahadevan)

REDDING, JAMES Medford Spin Qubits in Double and Triple Quantum Dots . (Marcus/Yacoby)

NARAYAN, GAUTHAM Light Curves of Type Ia Supernovae and Preliminary Cosmological Constraints from the ESSENCE Survey . (Stubbs)

PAN, TONY Properties of Unusually Luminous Supernovae . (Loeb)

RASTOGI, ASHWIN Brane Constructions and BPS Spectra . (Vafa)

RUEL, JONATHAN Optical Spectroscopy and Velocity Dispersions of SZ-selected Galaxy Clusters . (Stubbs)

SHER, MENG JU Intermediate Band Properties of Femtosecond-Laser Hyperdoped Silicon . (Mazur)

TANG, YIQIAO Chirality of Light and Its Interaction with Chiral Matter . (Cohen)

TAYCHATANAPAT, THITI From Hopping to Ballistic Transport in Graphene-Based Electronic Devices . (Jarillo-Herrero/Yacoby)

VISBAL, ELI Future Probes of Cosmology and the High-Redshift Universe . (Loeb)

ZELJKOVIC, ILIJA Visualizing the Interplay of Structural and Electronic Disorders in High-Temperature Superconductors using Scanning Tunneling Microscopy . (Hoffman)

ZEVI DELLA PORTA, GIOVANNI Measurement of the Cross-Section for W Boson Production in Association With B-Jets in Proton-Proton Collisions at √S = 7 Tev at the LHC Using the ATLAS Detector . (Franklin)

AU, YAT SHAN LinkInelastic collisions of atomic thorium and molecular thorium monoxide with cold helium-3. (Doyle)

BARR, MATTHEW Coherent Scattering in Two Dimensions: Graphene and Quantum Corrals . (Heller)

CHANG, CHI-MING Higher Spin Holography. (Yin)

CHU, YIWEN Quantum optics with atom-like systems in diamond. (Lukin)

GATANOV, TIMUR Data-Driven Analysis of Mitotic Spindles . (Needleman/Kaxiras)

GRINOLDS, MICHAEL Nanoscale magnetic resonance imaging and magnetic sensing using atomic defects in diamond. (Yacoby)

GUERRA, RODRIGO Elasticity of Compressed Emulsions . (Weitz)

HERRING, PATRICK LinkLow Dimensional Carbon Electronics. (Jarillo-Herrero/Yacoby)

HESS, PAUL W. LinkImproving the Limit on the Electron EDM: Data Acquisition and Systematics Studies in the ACME Experiment. (Gabrielse)

HOU, JENNIFER Dynamics in Biological Soft Materials . (Cohen)

HUBER, FLORIAN Site-Resolved Imaging with the Fermi Gas Microscope. (Greiner)

HUTZLER, NICHOLAS A New Limit on the Electron Electric Dipole Moment . (Doyle)

KESTIN, GREG Light-Shell Theory Foundations. (Georgi)

LYSOV, VYACHESLAV From Petrov-Einstein to Navier-Stokes. (Strominger)

MA, RUICHAO Engineered Potentials and Dynamics of Ultracold Quantum Gases under the Microscope. (Greiner)

MAURER, PETER Coherent control of diamond defects for quantum information science and quantum sensing. (Lukin)

NG, GIM SENG Aspects of Symmetry in de Sitter Space. (Strominger)

NICOLAISEN, LAUREN Distortions in Genealogies due to Purifying Selection. (Desai)

NURGALIEV, DANIYAR A Study of the Radial and Azimuthal Gas Distribution in Massive Galaxy Clusters. (Stubbs)

RUBIN, DOUGLAS Properties of Dark Matter Halos and Novel Signatures of Baryons in Them . (Loeb)

RUSSELL, EMILY Structure and Properties of Charged Colloidal Systems. (Weitz)

SHIELDS, BRENDAN Diamond Platforms for Nanoscale Photonics and Metrology. (Lukin)

SPAUN, BENJAMIN A Ten-Fold Improvement to the Limit of the Electron Electric Dipole Moment. (Gabrielse)

YAO, NORMAN Topology, Localization, and Quantum Information in Atomic, Molecular and Optical Systems. (Lukin)

YEE, MICHAEL Scanning Tunneling Spectroscopy of Topological Insulators and Cuprate Superconductors. (Hoffman)

BENJAMIN, DAVID ISAIAH Impurity Physics in Resonant X-Ray Scattering and Ultracold Atomic Gases . (Demler)

BEN-SHACH, GILAD Theoretical Considerations for Experiments to Create and Detect Localised Majorana Modes in Electronic Systems. (Halperin/Yacoby)

CHANG, WILLY Superconducting Proximity Effect in InAs Nanowires . (Marcus/Yacoby)

CHUNG, HYEYOUN Exploring Black Hole Dynamics . (Randall)

INCORVIA, JEAN ANNE CURRIVAN Nanoscale Magnetic Materials for Energy-Efficient Spin Based Transistors. (Westervelt)

FEIGE, ILYA ERIC ALEXANDER Factorization and Precision Calculations in Particle Physics. (Schwartz)

FRENZEL, ALEX Terahertz Electrodynamics of Dirac Fermions in Graphene. (Hoffman)

HSU, CHIA WEI Novel Trapping and Scattering of Light in Resonant Nanophotonic Structures. (Cohen)

JORGOLLI, MARSELA Integrated nanoscale tools for interrogating living cells. (Park)

KALRA, RITA RANI An Improved Antihydrogen Trap. (Gabrielse)

KOLKOWITZ, SHIMON JACOB Nanoscale Sensing with Individual Nitrogen-Vacancy Centers in Diamond. (Lukin)

LAVRENTOVICH, MAXIM OLEGOVICH Diffusion, Absorbing States, and Nonequilibrium Phase Transitions in Range Expansions and Evolution. (Nelson)

LIU, BO Selected Topics in Scattering Theory: From Chaos to Resonance. (Heller)

LOCKHART, GUGLIELMO PAUL Self-Dual Strings of Six-Dimensional SCFTs . (Vafa)

MAGKIRIADOU, SOFIA Structural Color from Colloidal Glasses. (Manoharan)

MCIVER, JAMES W. Nonlinear Optical and Optoelectronic Studies of Topological Insulator Surfaces. (Hoffman)

MEISNER, AARON MICHAEL Full-sky, High-resolution Maps of Interstellar Dust. (Finkbeiner)

MERCURIO, KEVIN MICHAEL A Search for the Higgs Boson Produced in Association with a Vector Boson Using the ATLAS Detector at the LHC. (Huth)

NOWOJEWSKI, ANDRZEJ KAZIMIERZ Pathogen Avoidance by Caenorhabditis Elegans is a Pheromone-Mediated Collective Behavior. (Levine)

PISKORSKI, JULIA HEGE Cooling, Collisions and non-Sticking of Polyatomic Molecules in a Cryogenic Buffer Gas Cell. (Doyle)

SAJJAD, AQIL An Effective Theory on the Light Shell. (Georgi)

SCHADE, NICHOLAS BENJAMIN Self-Assembly of Plasmonic Nanoclusters for Optical Metafluids. (Manoharan)

SHULMAN, MICHAEL DEAN Entanglement and Metrology with Singlet-Triplet Qubits. (Yacoby)

SPEARMAN, WILLIAM R. Measurement of the Mass and Width of the Higgs Boson in the H to ZZ to 4l Decay Channel Using Per-Event Response Information. (Guimaraes da Costa)

THOMPSON, JEFFREY DOUGLAS A Quantum Interface Between Single Atoms and Nanophotonic Structures. (Lukin)

WANG, TOUT TAOTAO Small Diatomic Alkali Molecules at Ultracold Temperatures. (Doyle)

WONG, CHIN LIN Beam Characterization and Systematics of the Bicep2 and Keck Array Cosmic Microwave Background Polarization Experiments. (Kovac)

AGARWAL, KARTIEK Slow Dynamics in Quantum Matter: the Role of Dimensionality, Disorder and Dissipation. (Demler)

ALLEN, MONICA Quantum electronic transport in mesoscopic graphene devices. (Yacoby)

CHAE, EUNMI Laser Slowing of CaF Molecules and Progress towards a Dual-MOT for Li and CaF. (Doyle)

CHOTIBUT, THIPARAT Aspects of Statistical Fluctuations in Evolutionary and Population Dynamics. (Nelson)

CHOWDHURY, DEBANJAN Interplay of Broken Symmetries and Quantum Criticality in Correlated Electronic Systems. (Sachdev)

CLARK, BRIAN Search for New Physics in Dijet Invariant Mass Spectrum. (Huth)

FARHI, DAVID Jets and Metastability in Quantum Mechanics and Quantum Field Theory. (Schwartz)

FORSYTHE, MARTIN Advances in Ab Initio Modeling of the Many-Body Effects of Dispersion Interactions in Functional Organic Materials. (Aspuru-Guzik/Ni)

GOOD, BENJAMIN Molecular evolution in rapidly evolving populations. (Desai)

HART, SEAN Electronic Phenomena in Two-Dimensional Topological Insulators. (Yacoby)

HE, YANG Scanning Tunneling Microscopy Study on Strongly Correlated Materials. (Hoffman)

HIGGINBOTHAM, ANDREW Quantum Dots for Conventional and Topological Qubits. (Marcus/Westervelt)

HUANG, DENNIS Nanoscale Investigations of High-Temperature Superconductivity in a Single Atomic Layer of Iron Selenide. (Hoffman)

ISAKOV, ALEXANDER The Collective Action Problem in a Social and a Biophysical System. (Mahadevan)

KLALES, ANNA A classical perspective on non-diffractive disorder. (Heller)

KOBY, TIMOTHY Development of a Trajectory Model for the Analysis of Stratospheric Water Vapor. (Anderson/Heller)

KOMAR, PETER Quantum Information Science and Quantum Metrology: Novel Systems and Applications. (Lukin)

KUCSCKO, GEORG Coupled Spins in Diamond: From Quantum Control to Metrology and Many-Body Physics. (Lukin)

LAZOVICH, TOMO Observation of the Higgs boson in the WW* channel and search for Higgs boson pair production in the bb ̅bb ̅ channel with the ATLAS detector. (Franklin)

LEE, JUNHYUN Novel quantum phase transitions in low-dimensional systems. (Sachdev)

LIN, YING-HSUAN Conformal Bootstrap in Two Dimensions. (Yin)

LUCAS, ANDREW Transport and hydrodynamics in holography, strange metals and graphene. (Sachdev)

MACLAURIN, DOUGAL Modeling, Inference and Optimization with Composable Differentiable Procedures. (Adams/Cohen)

PARSONS, MAXWELL Probing the Hubbard Model with Single-Site Resolution. (Greiner)

PATEJ, ANNA Distributions of Gas and Galaxies from Galaxy Clusters to Larger Scales. (Eisenstein/Loeb/Finkbeiner)

PITTMAN, SUZANNE The Classical-Quantum Correspondence of Polyatomic Molecules. (Heller)

POPA, CRISTINA Simulating the Cosmic Gas: From Globular Clusters to the Most Massive Haloes. (Randall)

PORFYRIADIS, ACHILLEAS Gravitational waves from the Kerr/CFT correspondence . (Strominger)

PREISS, PHILIPP Atomic Bose-Hubbard systems with single-particle control. (Greiner)

SHAO, SHU-HENG Supersymmetric Particles in Four Dimensions. (Yin)

YEN, ANDY Search for Weak Gaugino Production in Final States with One Lepton, Two b-jets Consistent with a Higgs Boson, and Missing Transverse Momentum with the ATLAS detector. (Huth)

BERCK, MATTHEW ELI Reconstructing and Analyzing the Wiring Diagram of the Drosophila Larva Olfactory System. (Samuel)

COUGHLIN, MICHAEL WILLIAM Gravitational Wave Astronomy in the LSST Era. (Stubbs)

DIMIDUK, THOMAS Holographic Microscopy for Soft Matter and Biophysics. (Manoharan)

FROST, WILLIAM THOMAS Tunneling in Quantum Field Theory and the Fate of the Universe. (Schwartz)

JERISON, ELIZABETH Epistasis and Pleiotropy in Evolving Populations. (Desai)

KAFKA, GARETH A Search for Sterile Neutrinos at the NOνA Far Detector. (Feldman)

KOSHELEVA, EKATERINA Genetic Draft and Linked Selection in Rapidly Adapting Populations. (Desai)

KOSTINSKI, SARAH VALERIE Geometrical Aspects of Soft Matter and Optical Systems. (Brenner)

KOZYRYEV, IVAN Laser Cooling and Inelastic Collisions of the Polyatomic Radical SrOH. (Doyle)

KRALL, REBECCA Studies of Dark Matter and Supersymmetry. (Reece)

KRAMER, ERIC DAVID Observational Constraints on Dissipative Dark Matter. (Randall)

LEE, LUCY EUNJU Network Analysis of Transcriptome to Reveal Interactions Among Genes and Signaling Pathways. (Levine)

LOVCHINSKY, IGOR Nanoscale Magnetic Resonance Spectroscopy Using Individual Spin Qubits. (Lukin)

LUPSASCA, ALEXANDRU The Maximally Rotating Black Hole as a Critical Point in Astronomy. (Strominger)

MANSURIPUR, TOBIAS The Effect of Intracavity Field Variation on the Emission Properties of Quantum Cascade Lasers. (Capasso/Yacoby)

MARANTAN, ANDREW WILLIAM The Roles of Randomness in Biophysics: From Cell Growth to Behavioral Control. (Mahadevan)

MASHIAN, NATALIE Modeling the Constituents of the Early Universe. (Loeb/Stubbs)

MAZURENKO, ANTON Probing Long Range Antiferromagnetism and Dynamics in the Fermi-Hubbard Model. (Greiner)

MITRA, PRAHAR Asymptotic Symmetries in Four Dimensional Gauge and Gravity Theories. (Strominger)

NEAGU, IULIA ALEXANDRA Evolutionary Dynamics of Infection. (Nowak/Prentiss)

PETRIK WEST, ELIZABETH A Thermochemical Cryogenic Buffer Gas Beam Source of ThO for Measuring the Electric Dipole Moment of the Electron. (Doyle)

RUDELIUS, THOMAS Topics in the String Landscape and the Swampland. (Vafa)

SAKLAYEN, NABIHA Laser-Activated Plasmonic Substrates for Intracellular Delivery. (Mazur)

SIPAHIGIL, ALP Quantum Optics with Diamond Color Centers Coupled to Nanophotonic Devices. (Lukin)

SUN, SIYUAN Search for the Supersymmetric Partner to the Top Quark Using Recoils Against Strong Initial State Radiation. (Franklin)

TAI, MING ERIC Microscopy of Interacting Quantum Systems. (Greiner)

TOLLEY, EMMA Search for Evidence of Dark Matter Production in Monojet Events with the ATLAS Detector. (Morii)

WILSON, ALYSSA MICHELLE New Insights on Neural Circuit Refinement in the Central Nervous System: Climbing Fiber Synapse Elimination in the Developing Mouse Cerebellum Studied with Serial-Section Scanning Electron Microscopy. (Lichtman/Samuel)

BAUCH, ERIK Optimizing Solid-State Spins in Diamond for Nano- to Millimeter scale Magnetic Field Sensing. (Walsworth)

BRACHER, DAVID OLMSTEAD Development of photonic crystal cavities to enhance point defect emission in silicon carbide. (Hu: SEAS)

CHAN, STEPHEN KAM WAH Orthogonal Decompositions of Collision Events and Measurement Combinations in Standard Model $VH\left(b\bar{b}\right)$ Searches with the ATLAS Detector. (Huth)

CHATTERJEE, SHUBHAYU Transport and symmetry breaking in strongly correlated matter with topological order. (Sachdev)

CHOI, SOONWON Quantum Dynamics of Strongly Interacting Many-Body Systems. (Lukin)

CONNORS, JAKE Channel Length Scaling in Microwave Graphene Field Effect Transistors. (Kovac)

DAHLSTROM, ERIN KATRINA Quantifying and modeling dynamics of heat shock detection and response in the intestine of Caenorhabditis elegans. (Levine)

DAYLAN, TANSU A Transdimensional Perspective on Dark Matter. (Finkbeiner)

DOVZHENKO, YULIYA Imaging of Condensed Matter Magnetism Using an Atomic-Sized Sensor. (Yacoby)

EVANS, RUFFIN ELEY An integrated diamond nanophotonics platform for quantum optics. (Lukin)

FLEMING, STEPHEN Probing nanopore - DNA interactions with MspA. (Golovchenko)

FRYE, CHRISTOPHER Understanding Jet Physics at Modern Particle Colliders. (Schwartz)

FU, WENBO The Sachdev-Ye-Kitaev model and matter without quasiparticles. (Sachdev)

GOLDMAN, MICHAEL LURIE Coherent Optical Control of Atom-Like Defects in Diamond: Probing Internal Dynamics and Environmental Interactions. (Lukin)

HE, TEMPLE MU On Soft Theorems and Asymptotic Symmetries in Four Dimensions. (Strominger)

HOYT, ROBERT Understanding Catalysts with Density Functional Theory and Machine Learning. (Kaxiras)

KAPEC, DANIEL STEVEN Aspects of Symmetry in Asymptotically Flat Spacetimes. (Strominger)

LEE, ALBERT Mapping the Relationship Between Interstellar Dust and Radiation in the Milky Way. (Finkbeiner)

LEE, JAEHYEON Prediction and Inference Methods for Modern Astronomical Surveys (Eisenstein, Finkbeiner)

LUKIN, ALEXANDER Entanglement Dynamics in One Dimension -- From Quantum Thermalization to Many-Body Localization (Greiner)

NOVITSKI, ELISE M. Apparatus and Methods for a New Measurement of the Electron and Positron Magnetic Moments. (Gabrielse)

PATHAK, ABHISHEK Holography Beyond AdS/CFT: Explorations in Kerr/CFT and Higher Spin DS/CFT. (Strominger)

PETERMAN, NEIL Sequence-function models of regulatory RNA in E. coli. (Levine)

PICK, ADI Spontaneous Emission in Nanophotonics. (Johnson: MIT)

PO, HOI CHUN Keeping it Real: An Alternative Picture for Symmetry and Topology in Condensed Matter Systems. (Vishwanath)

REN, HECHEN Topological Superconductivity in Two-Dimensional Electronic Systems. (Yacoby)

ROXLO, THOMAS Opening the black box of neural nets: case studies in stop/top discrimination. (Reece)

SHTYK, OLEKSANDR Designing Singularities in Electronic Dispersions (Chamon, Demler)

TONG, BAOJIA Search for pair production of Higgs bosons in the four b quark final state with the ATLAS detector. (Franklin)

WHITSITT, SETH Universal non-local observables at strongly interacting quantum critical points. (Sachdev)

YAN, KAI Factorization in hadron collisions from effective field theory. (Schwartz)

AMATOGRILL, JESSE A Fast 7Li-based Quantum Simulator (Ketterle, Greiner)

BARON, JACOB Tools for Higher Dimensional Study of the Drosophila Larval Olfactory System (Samuel)

BUZA, VICTOR Constraining Primordial Gravitational Waves Using Present and Future CMB Experiments (Kovac)

CHAEL, ANDREW Simulating and Imaging Supermassive Black Hole Accretion Flows (Narayan, Dvorkin)

CHIU, CHRISTIE Quantum Simulation of the Hubbard Model (Greiner)

DIPETRILLO, KARRI Search for Long-Lived, Massive Particles in Events with a Displaced Vertex and a Displaced Muon Using sqrt{s} = 13 TeV pp-Collisions with the ATLAS Detector (Franklin)

FANG, SHIANG Multi-scale Theoretical Modeling of Twisted van der Waals Bilayers (Kaxiras)

GAO, PING Traversable Wormholes and Regenesis (Jafferis)

GONSKI, JULIA Probing Natural Supersymmetry with Initial State Radiation: the Search for Stops and Higgsinos at ATLAS (Morii)

HARVEY, SHANNON Developing Singlet-Triplet Qubits in Gallium Arsenide as a Platform for Quantum Computing (Yacoby)

JEFFERSON, PATRICK Geometric Deconstruction of Supersymmetric Quantum Field Theories (Vafa)

KANG, MONICA JINWOO Two Views on Gravity: F-theory and Holography (Jafferis)

KATES-HARBECK, JULIAN Tackling Complexity and Nonlinearity in Plasmas and Networks Using Artificial Intelligence and Analytical Methods (Desai, Nowak)

KLEIN, ELLEN Structure and Dynamics of Colloidal Clusters (Manoharan)

LEVIN, ANDREI Single-Electron Probes of Two-Dimensional Materials (Yacoby)

LIU, XIAOMENG Correlated Electron States in Coupled Graphene Double-Layer Heterostructures (Kim)

LIU, LEE Building Single Molecules – Reactions, Collisions, and Spectroscopy of Two Atoms (Ni)

MARABLE, KATHRYN Progress Towards a Sub-ppb Measurement of the Antiproton Magnetic Moment (Gabrielse)

MARSHALL, MASON New Apparatus and Methods for the Measurement of the Proton and Antiproton Magnetic Moments (Gabrielse)

MCNAMARA, HAROLD Synthetic Physiology: Manipulating and Measuring Biological Pattern Formation with Light (Cohen)

MEMET, EDVIN Parking, Puckering, and Peeling in Small Soft Systems (Mahadevan)

MUKHAMETZHANOV, BAURZHAN Bootstrapping High-Energy States in Conformal Field Theories (Jafferis)

OLSON, JOSEPH Plasticity and Firing Rate Dynamics in Leaky Integrate-and-Fire Models of Cortical Circuits (Kreiman)

PANDA, CRISTIAN Order of Magnitude Improved Limit on the Electric Dipole Moment of the Electron (Gabrielse)

PASTERSKI, SABRINA Implications of Superrotations (Strominger)

PATE, MONICA Aspects of Symmetry in the Infrared (Strominger)

PATEL, AAVISHKAR Transport, Criticality, and Chaos in Fermionic Quantum Matter at Nonzero Density (Sachdev)

PHELPS, GREGORY A Dipolar Quantum Gas Microscope (Greiner)

RISPOLI, MATTHEW Microscopy of Correlations at a Non-Equilibrium Phase Transition (Greiner)

ROLOFF, JENNIFER Exploring the Standard Model and beyond with jets from proton-proton collisions at sqrt(s)=13 TeV with the ATLAS Experiment (Huth)

ROWAN, MICHAEL Dissipation of Magnetic Energy in Collisionless Accretion Flows (Narayan and Morii)

SAFIRA, ARTHUR NV Magnetic Noise Sensing and Quantum Information Processing, and Llevitating Micromagnets over Type-II Superconductors (Lukin)

SHI, YICHEN Analytical Steps Towards the Observation of High-Spin Black Holes (Strominger)

THOMSON, ALEXANDRA Emergent Dapless Fermions in Strongly-Correlated Phases of Matter and Quantum Critical Points (Sachdev)

WEBB, TATIANA The Nanoscale Structure of Charge Order in Cuprate Superconductor Bi2201 (Hoffman)

WESSELS, MELISSA Progress Toward a Single-Electron Qubit in an Optimized Planar Penning Trap (Gabrielse)

WILLIAMS, MOBOLAJI Biomolecules, Combinatorics, and Statistical Physics (Shakhnovich, Manoharan)

XIONG, ZHAOXI Classification and Construction of Topological Phases of Quantum Matter (Vishwanath)

ZOU, LIUJUN An Odyssey in Modern Quantum Many-Body Physics (Todadri, Sachdev)

ANDEREGG, LOÏC Ultracold molecules in optical arrays: from laser cooling to molecular collisions (Doyle)

BALTHAZAR, BRUNO 2d String Theory and the Non-Perturbative c=1 Matrix Model (Yin)

BAUM, LOUIS Laser cooling and 1D magneto-optical trapping of calcium monohydroxide (Doyle)

CARR, STEPHEN Moiré patterns in 2D materials (Kaxiras)

COLLIER, SCOTT Aspects of local conformal symmetry in 1+1 dimensions (Yin)

DASGUPTA, ISHITA Algorithmic approaches to ecological rationality in humans and machines (Mahadevan)

DILLAVOU, SAMUEL Hidden Dynamics of Static Friction (Manoharan)

FLAMANT, CEDRIC Methods for Converging Solutions of Differential Equations: Applying Imaginary Time Propagation to Density Functional Theory and Unsupervised Neural Networks to Dynamical Systems (Kaxiras)

HUANG, KO-FAN (KATIE) Superconducting Proximity Effect in Graphene (Kim)

JONES, NATHAN Toward Antihydrogen Spectroscopy (Gabrielse)

KABCENELL, AARON Hybrid Quantum Systems with Nitrogen Vacancy Centers and Mechanical Resonators (Lukin)

KATES-HARBECK, JULIAN Tackling complexity and nonlinearity in plasmas and networks using artificial intelligence and analytical methods (Desai)

KIVLICHAN, IAN Faster quantum simulation of quantum chemistry with tailored algorithms and Hamiltonian s (Aspuru-Guzik, Lukin)

KOSOWSKY, MICHAEL Topological Phenomena in Two-Dimensional Electron Systems (Yacoby)

KUATE DEFO, RODRICK Modeling Formation and Stability of Fluorescent Defects in Wide-Bandgap Semiconductors (Kaxiras)

LEE, JONG YEON Fractionalization, Emergent Gauge Dynamics, and Topology in Quantum Matter (Vishwanath)

MARABLE, KATHRYN Progress towards a sub-ppb measurement of the antiproton magnetic moment (Gabrielse)

MCNAMARA, HAROLD Synthetic Physiology: Manipulating and measuring biological pattern formation with light (Cohen)

MEMET, EDVIN Parking, puckering, and peeling in small soft systems (Mahadevan)

NGUYEN, CHRISTIAN Building quantum networks using diamond nanophotonics (Lukin)

OLSON, JOSEPH Plasticity and Firing Rate Dynamics in Leaky Integrate-and-Fire Models of Cortical Circuits (Samuel)

ORONA, LUCAS Advances In The Singlet-Triplet Spin Qubit (Yacoby)

RACLARIU, ANA-MARIA On Soft Symmetries in Gravity and Gauge Theory (Strominger)

RAVI, AAKASH Topics in precision astrophysical spectroscopy (Dvorkin)

SHI, JING Quantum Hall Effect-Mediated Josephson Junctions in Graphene (Kim)

SHI, ZHUJUN Manipulating light with multifunctional metasurfaces (Capasso, Manoharan)

STEINBERG, JULIA Universal Aspects of Quantum-Critical Dynamics In and Out of Equilibrium (Sachdev)

WILD, DOMINIK Algorithms and Platforms for Quantum Science and Technology (Lukin)

WU, HAI-YIN Biophysics of Mitotic Spindle Positioning in Caenorhabditis elegans Early Embryos (Needleman)

YU, LI Quantum Dynamics in Various Noise Scenarios (Heller)

BARKLEY, SOLOMON Applying Bayesian Inference to Measurements of Colloidal Dynamics (Manoharan)

BHASKAR, MIHIR Diamond Nanophotonic Quantum Networks (Lukin)

BINTU, BOGDAN Genome-scale imaging: from the subcellular structure of chromatin to the 3D organization of the peripheral olfactory system (Dulac, Zhuang, Nelson)

CHEN, MINGYUE On knotted surfaces in R 4 (Taubes, Vafa)

CHO, MINJAE Aspects of string field theory (Yin)

DIAZ RIVERO, ANA Statistically Exploring Cracks in the Lambda Cold Dark Matter Model (Dvorkin)

DWYER, BO NV centers as local probes of two-dimensional materials (Lukin)

GATES, DELILAH Observational Electromagnetic Signatures of Spinning Black Holes (Strominger)

HANNESDOTTIR, HOFIE Analytic Structure and Finiteness of Scattering Amplitudes (Schwartz)

HART, CONNOR Experimental Realization of Improved Magnetic Sensing and Imaging in Ensembles of Nitrogen Vacancy Centers in Diamond (Walsworth, Park)

HÉBERT, ANNE A Dipolar Erbium Quantum Gas Microscope (Greiner)

JI, GEOFFREY Microscopic control and dynamics of a Fermi-Hubbard system (Greiner)

JOE, ANDREW Interlayer Excitons in Atomically Thin van der Waals Semiconductor Heterostructures (Kim)

KEESLING, ALEXANDER Quantum Simulation and Quantum Information Processing with Programmable Rydberg Atom Arrays (Lukin)

KRAHN, AARON Erbium gas quantum microscope (Greiner)

LANGELLIER, NICHOLAS Analytical and Statistical Models for Laboratory and Astrophysical Precision Measurements (Walsworth, Dvorkin)

LEVINE, HARRY Quantum Information Processing and Quantum Simulation with Programmable Rydberg Atom Arrays (Lukin)

LEVONIAN, DAVID A Quantum Network Node Based on the Silicon Vacancy Defect in Diamond (Lukin)

LIN, ALBERT Characterizing chemosensory responses of C. elegans with multi-neuronal imaging (Samuel)

LIU, SHANG Symmetry, Topology and Entanglement in Quantum Many-Body Systems (Vishwanath)

LIU, YU Bimolecular chemistry at sub-microkelvin temperatures (Ni)

MACHIELSE, BART Electronic and Nanophotonic Integration of a Quantum Network Node in Diamond (Lukin)

MELISSA, MATTHEW Divergence and diversity in rapidly evolving populations (Desai)

MITCHELL, JAMES Investigations into Resinicolous Fungi (Pfister, Samuel)

MONDRIK, NICHOLAS Calibration Hardware and Methodology for Large Photometric Surveys (Stubbs)

NANDE, ANJALIKA Mathematical modeling of drug resistance and the transmission of SARS-CoV-2 (Hill, Desai)

PLUMMER, ABIGAIL Reactions and instabilities in fluid layers and elastic sheets (Nelson)

RODRIGUEZ, VICTOR Perturbative and Non-Perturbative Aspects of Two-Dimensional String Theory (Yin)

ROSENFELD, EMMA Novel techniques for control and transduction of solid-state spin qubits (Lukin)

SAMUTPRAPHOOT, POLNOP A quantum network node based on a nanophotonic interface for atoms in optical tweezers (Lukin)

SCHNEIDER, ELLIOT Stringy ER = EPR (Jafferis)

ST. GERMAINE, TYLER Beam Systematics and Primordial Gravitational Wave Constraints from the BICEP/Keck Array CMB Experiments (Kovac)

TORRISI, STEVEN Materials Informatics for Catalyst Stability & Functionality (Kaxiras, Kozinsky)

TURNER, MATTHEW Quantum Diamond Microscopes for Biological Systems and Integrated Circuits (Walsworth, Cohen)

VENKAT, SIDDHARTH Modeling Excitons in Transition Metal Dichalcogenide Monolayers (Heller)

VENKATRAMANI, ADITYA Quantum nonlinear optics: controlling few-photon interactions (Lukin, Vuletić)

WANG, ANN A search for long-lived particles with large ionization energy loss in the ATLAS silicon pixel detector using 139 fb^{−1} of sqrt{s} = 13 TeV pp collisions (Franklin)

WILBURN, GREY An Inverse Statistical Physics Method for Biological Sequence Analysis (Eddy, Nelson)

XU, LINDA Searching for Dark Matter in the Early and Late Universe (Randall)

YI, KEXIN Neural Symbolic Machine Reasoning in the Physical World (Mahadevan, Finkbeiner)

YU, YICHAO Coherent Creation of Single Molecules from Single Atoms (Ni)

ZHOU, LEO Complexity, Algorithms, and Applications of Programmable Quantum Many-Body Systems (Lukin)

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Thesis Information

Upcoming thesis defenses.

If you are defending this term and do not see your information listed, please contact Sydney Miller in the APO.

Forming a Thesis Committee

When : Doctoral Students – After completing the written and oral exams and generally by the beginning of their third Year of study. Forming their committees at this stage will allow students to consult with all members of the committee during their studies and can provide additional advice and mentorship for them.

How : Register for thesis research under subject number 8.ThG, form a thesis committee, meet with full committee, and submit a formal thesis proposal to the department.

Thesis Committee Formation

Student should consult with their Research Supervisor to discuss the Doctoral Thesis Committee Proposal Form which will name the 3 required members of the Physics Doctoral Committee and a descriptive preliminary thesis title.

Doctoral Committee must include 3 members with MIT Physics faculty appointments:

Committee Chair: Research Supervisor from MIT Physics Faculty or Research Supervisor from outside MIT Physics + Co-Supervisor/Chair from MIT Physics Faculty
Selected Reader: from MIT Physics Faculty (in the same/similar research area, selected by student and supervisor)
Assigned Reader: from MIT Physics Faculty (in different research area, selected by the Department’s faculty Graduate Coordinator.)

The Form should include the names of the Student, Chair, and Selected Reader and a Thesis Title, when it is forwarded to the Academic Programs Office via email to [email protected] and Sydney will work with Faculty Graduate Coordinator Will Detmold , who will identify the Assigned Reader.

Following the consultation with their supervisor, the student should reach out to the proposed Selected Reader to secure an electronic signature or email confirmation in lieu of signature to serve on this committee. (Form should include either signature or date of email agreement.) It will take approximately 2-3 weeks before an Assigned Reader will be added and Sydney will provide an introduction to this final member of your Doctoral Committee. Please note: you may not form your committee and defend your thesis in the same semester.

Thesis Committee Meeting and Proposal

Once the Thesis Committee is established, the student should send all members a draft description of the proposed thesis topic and set up the first committee meeting with all members attending together in real time. A formal 2-page written Thesis Proposal should result from this important meeting and be sent to Sydney for the student’s academic record.

Thesis Proposal

You should discuss your thesis research with your committee members all together in real time at your first committee meeting. Following this full discussion about your thesis topic, please write up your formal Thesis Proposal to reflect the mutually-agreed thesis plans and forward the Proposal to the graduate program at the APO using [email protected] for Sydney to document in the department’s academic records.

Thesis Research

Following the formation of the doctoral committee and submission of the thesis proposal, the student will continue to work on their thesis research in consultation with their Research Supervisor and other members of their Committee. This important communication paves the way for the thesis defense and degree completion.

When students are ready to defend, they should complete an ‘ Application for Advanced Degree ’ with the Registrar and schedule a thesis defense with all committee members attending in real time, whether in person or by video. Announcements for the defense will be coordinated by the Academic Programs Office and students should be in close contact with Sydney Miller during their final term or study.

Further details about this last stage of your studies will be available separately.

Thesis Defense

If there is even a slight possibility that you may finish this term, please complete an Application for Advanced Degree at the Registrar’s website at the beginning of the term. It is easy to remove your name if your plans change, but this timely step will avoid late fees!

Once you have scheduled your defense, please send this information to Sydney at [email protected] :

Thesis Title:
Committee Members:
Meeting Details: (can be sent in the final week before the defense)

She will create the email notifications for our physics community and the MIT Events and Physics Calendar listings. This information you provide her is also used to generate the defense grade sheet for your defense.

Please send your committee members a thesis draft to help them prepare for your defense and plan to spend around two weeks making thesis revisions after your successful defense. The date you submit your thesis document to the department will determine whether it is for a Fall, Spring, or Summer degree.

Thesis Formatting

Archival copies of all theses must adhere carefully to principles specified by the MIT Libraries for formatting and submission. For complete information about how to format your thesis, refer to the Specifications for Thesis Preparation .

Graduate Program Coordinator Sydney Miller can review your title page and abstract for accuracy before you submit the thesis. You may send these to her at [email protected].

Required Signatures and Documentation

Signatures: The MIT Archives require an electronic PDF document and the Department needs a separate additional stand-alone title page with electronic/scanned signatures of the student, research supervisor, and co-supervisor (if applicable). Theses are accepted by Associate Department Head, Professor Lindley Winslow . Please send your documents to [email protected] and the APO staff will forward your thesis submitted to the MIT Library Archives.
Thesis defense grade sheets: Before accepting a PhD thesis, the Academic Programs Office must have a signed thesis defense grade sheet from the research supervisor indicating a “Pass” on the thesis defense.
Thesis letter grade: Before accepting an SM thesis, Academic Programs must have received a letter or email from the research supervisor, assigning a final thesis grade of A, B, or C.

Finalizing and Submitting your Thesis to MIT

Departments collect the thesis documents on behalf of the MIT Thesis Library Archives and Physics graduate students will submit their thesis to Sydney Miller. Review overall information from MIT about thesis specifications and format .

Please see the attached doctoral title page format for Physics and send your draft of the title/cover page and abstract to Sydney for review and any necessary edits. Once these are approved, please prepare the full document, with pagination appropriate for double-sided printing.

Theses may be completed and signed on any date of the year and the degree requirements are completed when the thesis is submitted. This is the final day of student status and payroll. (International students are eligible for Optional Practical Training starting on the following day.)

MIT awards degrees at the end of each term:

Fall Term degree is in February. (Theses due second Friday in January.)
Spring Term degree is in May. (Theses due second Friday in May.)
Summer Term degree is in September. (Theses due second Friday in August.)

Thesis submissions are electronic files and you will submit the following to Sydney:

A complete thesis document, without signatures
A title page with electronic signatures from yourself, your supervisor (and co-supervisor, if required). Sydney will work with the Associate Head, Lindley Winslow , whose signature is required for the department and this will be added after you submit your document to the department/Sydney.
A separate abstract page

Doctoral students also complete and submit the Proquest/UMI form (PDF), with attached title page and abstract (no signatures).

In addition to submitting your thesis to the department for the library archives, you may also add your thesis to DSpace .

Digital Submission Guidelines

All theses are being accepted by the MIT Libraries in digital form only . Digital theses are submitted electronically to the Physics Department, along with a separate signed title page. Students on the degree list will receive specific guidance about submission from the Academic Programs Office.

General Thesis Policies

All theses are archived in the MIT Libraries. An archival fee must be paid before a student’s final candidacy for a degree can be officially approved.

After all required materials have been submitted to the Academic Programs Office, a thesis receipt will be sent by email.

Thesis Due Dates

Check the MIT Academic Calendar for deadlines to submit your online degree application.

Thesis submission deadlines Graduating in May: Second Friday in May Graduating in September: Second Friday in August Graduating in February: Second Friday in January We strongly recommend that your defense be scheduled at least three weeks prior to the submission date. Consult with Academic Administrator Shannon Larkin to determine your thesis submission timeline.

Thesis FAQs

The information on this page is applicable for both PhD and Masters (with the exception of an Oral defense) degree candidates.

How do I submit a Thesis Proposal? When is it due?

Students register for thesis research units and assemble a thesis committee in the term following passing the Oral Exam.

The first step is for the student and research supervisor to agree on a thesis topic. An initial Graduate Thesis Proposal Cover Sheet (PDF) (Master’s Degree candidates should see process in section below) must be submitted to Academic Programs by the second week of the term.

The form requires

an initial thesis title
the name and signature of the research supervisor
the name of one additional reader for the thesis committee agreed upon by the student and advisor

A third reader from the MIT Physics faculty, who is not in the same research area but whose background makes him or her an appropriate departmental representative on the committee, will be assigned by the Graduate Program Faculty Coordinator. If a student has a co-supervisor (because the main supervisor is from outside the MIT Physics faculty), the thesis committee will consist of four people: research supervisor, co-supervisor, selected reader, and assigned reader.

After the student is notified of the assigned reader, he or she should convene an initial thesis committee meeting within the same term. The student should also register for 8.THG beginning in this term, and in each term thereafter. 8.THG registration should be for up to 36 units, depending on whether the student is also still taking classes and/or receiving academic credit because of a teaching assistantship. All post-qual students should routinely register for a standard total 36 units.

Master’s degree candidates should complete an SM Thesis Proposal Cover Sheet (PDF). A second reader for the Master’s degree thesis committee is assigned by the Graduate Program Faculty Coordinator. Note that there is no public defense required for an SM degree.

See the Doctoral Guidelines for additional information.

I am going to graduate soon–what do I have to do in terms of paperwork etc.?

Please reference the Registrar’s complete graduation checklist . Students should reference this list at the START of the semester prior to graduation. Your research area’s administrative office and the Physics APO will also help you manage the final stage of your degree.

How do I get on/off the Degree List?

Fill out the Degree Application through the student section of WebSIS . Petitioning to be on the degree list for a particular commencement is required. Note that it is easier to be removed from the degree list to be added, so students are encouraged to apply for the degree list if there is any reasonable chance they will complete the PhD in the coming term.

The WebSIS degree list is used to communicate information about thesis defense announcements and grade sheets, thesis formats, and completion dates, so it is important to file a degree application to be on the list in a timely way. The standard deadline for filing a degree application without being assessed a late fee is the Friday of the first week of the term in which a student anticipates graduating. Removing oneself from the degree list requires an email to Academic Programs .

When is my thesis due? Can I get an extension?

Students can defend and submit their thesis on any dates that work for their committees, but MIT confers degrees only 3 times each year: in May, September and February. Thesis submission deadlines Graduating in May: Second Friday in May Graduating in September: Second Friday in August Graduating in February: Second Friday in January We strongly recommend that your defense be scheduled at least three weeks prior to the submission date. Consult with Academic Administrator Shannon Larkin to determine your thesis submission timeline.

Note that these deadlines are already more generous that the Institute thesis deadline. Students desiring extensions should contact the Academic Administrator, Shannon Larkin .

How do I find a room for my Thesis Defense?

Many Divisions have conference and/or seminar rooms which can be used for oral exams and defenses. These locations are recommended to keep your Thesis Defense comfortable and in familiar territory. Students who cannot book a room in their research area should contact Sydney Miller in the Physics APO to check availability of a Physics departmental conference room (often difficult to schedule due to heavy demand) or to help schedule a classroom through the Registrar’s Office.

When I submit my thesis to Physics Academic Programs, what do I need to bring?

Please refer to the Graduate Thesis Submission Guidelines .

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100 Interesting Physics Topics For Research Paper In 2023
100 Interesting Physics Topics For Research Paper In 2023. Searching for a topic in physics can be one of the more difficult challenges for students at any level. Teachers and professors want their students to research and write something original. They also want students to challenge themselves by pushing the envelope and studying new areas in ...
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Physics Research Area #1: Quantum Computing and Information. Quantum computing represents a groundbreaking shift in how we process information, leveraging the principles of quantum mechanics to solve problems that are currently beyond the reach of classical computers. For high school students interested in physics research, exploring quantum ...
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Some ideas of environmentally related physics research topics are: 23. New materials for the production of hydrogen fuel. 24. Analysis of emissions involved in the production, use, and disposal of products. 25. Nuclear fission or nuclear fusion energy as possible solutions to mitigate climate change.
What Are the Interesting Research Topics for High School Physics?
Projectile motion is an interesting research topic because objects being thrust through space appear to have some sort of force acting upon them. However, whether an object is dropped, thrown or shot, a projectile is moving through space under the force of gravity. Forensic science uses Newton's laws of motion to investigate crime scenes for ...
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Physics Research Paper Topics for University. Metamaterials: Creating the Impossible in Optics and Acoustics. Fluid Dynamics in Astrophysics: Stars, Galaxies, and Beyond. Tackling Turbulence: The Last Great Problem in Classical Physics. The Casimir Effect: Unearthing Quantum Force in the Vacuum.
100 Research Topic Ideas for High School Students
Here are five specific high school physics research topics and how you can approach them: 6. Investigate the properties and applications of quantum computing in modern technology. Quantum computing promises to revolutionize computing power. You can explore its theoretical foundations or practical applications, highlighting its potential to ...
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In this project, you would learn about topology in the context of knot theory. No formal knowledge of math is required to study knot theory! Idea by physics research mentor Adam. 3. Hijacking physics to do math for us. We use math to do a lot of things, like run computers or make predictions.
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Physics Research Topics for Grade 9. Investigating the properties of waves: amplitude, frequency, wavelength, and speed. The effect of temperature on the expansion and contraction of materials. The relationship between mass, velocity, and momentum. The behavior of light in different mediums and the concept of refraction.
LibGuides: Research Topic Ideas: Natural and Physical Sciences
Includes over 2,000 journals and 35,000 books published by Elsevier Science and its subsidiary publishers, including Academic Press, Cell Press, Pergamon, Mosby, and Saunders journals. Coverage is particularly strong for the life and physical sciences, medicine, and technical fields, but also includes some social sciences and humanities.
A List of 240 Physics Topics & Questions to Research
Create music by rubbing your finger against the rim of a glass. Experiment with several glasses filled with different amounts of water. Compare the free-fall speed of a Lego figure using various parachutes. Experiment with BEC to understand quantum mechanics. Make a windmill and describe how it works.
Physics Theses, Dissertations, and Masters Projects
Theses/Dissertations from 2020. PDF. A First-Principles Study of the Nature of the Insulating Gap in VO2, Christopher Hendriks. PDF. Competing And Cooperating Orders In The Three-Band Hubbard Model: A Comprehensive Quantum Monte Carlo And Generalized Hartree-Fock Study, Adam Chiciak. PDF.
(PDF) Particle physics in high-school education
The study resulted in a ranked list of the 13 most important topics to be included in particle physics professional development programmes. The highest-ranked topics are cosmology, the Standard ...
121+ Scientific Research Topics for High School Students
Here are some scientific research topics for high school students in chemistry: 1. Investigating the properties of different types of polymers. 2. Studying the effects of pH on chemical reactions. 3. Analyzing the composition of a local water source. 4. Exploring the chemistry of food preservation methods.
100 Amazing Physics Research Topics and Ideas
If you need a good topic for a physics research paper, read this blog. Here, we have suggested the 100 best physics research topics and ideas. ... If you are pursuing a degree in Physics, you will most likely be required to submit a thesis on the latest physics research topics. In general, physics is a broad field of study that is divided into ...
Research Topics
Research Topics. Our department is particularly interested in two of the Big Ideas that drive the National Science Foundation's long-term research agenda: The Quantum Leap: Leading the next Quantum Revolution and Harnessing Data for 21st Century Science and Engineering.Our faculty are also pursuing the following transformative opportunities for discovery science, identified by the Department ...
High school physics
This algebra-based course covers the main topics in high school introductory and honors physics, including motion, force, work, energy, momentum, collisions, torque, waves, sound, static electricity, and circuits. ... This course covers many topics in High school physics. Newer material aligned with the Next Generation Science Standards is ...
Physics Thesis Topics for High School
Physics Thesis Topics for High School - Free download as PDF File (.pdf), Text File (.txt) or read online for free. Scribd is the world's largest social reading and publishing site.
50 High School Senior Thesis Topics [PDF Included]
As high school seniors approach the end of their academic journey, one final task stands before them: the senior thesis. This capstone project is a culmination of their years of learning and provides an opportunity to delve deeply into a topic of their choosing. The senior thesis is a chance for students to showcase their ... <a title="50 High School Senior Thesis Topics [PDF Included]" class ...
Senior Theses
C+. The thesis contains an overview of a topic in physics, but the physics content is mostly superficial. The presentation may be inadequate, and there may be significant errors or omissions. C. The thesis contains a partial or superficial overview of a topic in physics. The thesis gives little evidence of understanding of the relevant physics.
PhD. Theses
View past theses (2011 to present) in the Dataspace Catalog of Ph.D Theses in the Department of Physics. View past theses (1996 to present) in the ProQuest Database. PhD. Theses 2024Nicholas QuirkTransport Experiments on Topological and Strongly Correlated ConductorsLeander ThieleGetting ready for new Data: Approaches to some Challenges in ...
Dissertations / Theses: 'High school physics'
Dissertations / Theses on the topic 'High school physics' To see the other types of publications on this topic, follow the link: High school physics. Author: Grafiati. Published: 4 June 2021 Last updated: 17 February 2022 Create a spot-on reference in APA, MLA, Chicago, Harvard, and other styles ...
Harvard PhD Theses in Physics, 2001-
The Use of Effective Variables in High Energy Physics. (Georgi/Arkani-Hamed) BOEHM, JOSHUA ADAM ALPERN, B.S.E. (Case Western Reserve University) 2003. ... Topics on Hadron Collider Physics. (Randall) KITAGAWA, TAKUYA New Phenomena in Non-Equilibrium Quantum Physics. (Demler) ... PhD Theses in Physics. PhD Thesis Help; Tax Information; 17 Oxford ...
Thesis Information » MIT Physics
Following this full discussion about your thesis topic, please write up your formal Thesis Proposal to reflect the mutually-agreed thesis plans and forward the Proposal to the graduate program at the APO using [email protected] for Sydney to document in the department's academic records.

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