MIT’s Master of Science in Physics provides the foundation for exploring theoretical and applied domains, from cosmology and quantum fields to experimental instrumentation. These projects empower students to tackle unanswered questions in the universe through simulation, experimentation, and computation.
Quantum Entanglement Simulation Using Tensor Networks
Dark Matter Detection via Cryogenic Calorimetry
Machine Learning for Galaxy Morphology Classification
Superconductivity Modeling in 2D Materials
Gravitational Waveform Analysis with LIGO Data
Topological Insulators and Quantum Hall Effects
Monte Carlo Methods in Statistical Thermodynamics
Quantum Error Correction Algorithms for Qubits
Computational Study of Bose-Einstein Condensates
High-Energy Particle Interaction Simulations Using GEANT4
Magnetic Field Mapping in Solar Corona Using MHD Equations
Modeling Hawking Radiation in Black Hole Analogues
Nuclear Fusion Reaction Kinetics in Tokamak Plasmas
Quantum Monte Carlo Methods for Many-Body Systems
Laser-Cooled Atomic Trap Simulation for Precision Measurement
Finite Element Analysis for Thermal Expansion in Crystals
AI-Assisted Neutrino Oscillation Data Interpretation
Modeling Acoustic Phonons in Nanostructures
Plasma Wakefield Acceleration Simulation
Cosmic Microwave Background Radiation Analysis
Quantum Cryptography Protocol Implementation in Simulators
Simulating Electron Transport in Quantum Dots
Magneto-Optical Traps for Cold Atom Research
Neutron Scattering Cross-Section Data Modeling
Strong-Field Laser Interaction with Molecular Systems
From quantum simulations to astrophysics data modeling — our mentors are here to guide you through high-impact physics research.
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