Yale’s M.S. in Applied Physics bridges foundational physical science with cutting-edge technological research. These thesis topics empower graduate students to contribute to emerging advancements in photonics, quantum systems, and semiconductor physics.
Simulation of Qubit Decoherence in Superconducting Systems
Development of Quantum Dot-Based Single-Photon Sources
Study of Nonlinear Optical Effects in Metamaterials
Modeling Carrier Mobility in Graphene-Based Transistors
Photonic Crystal Design for Light Manipulation at Nanoscale
Quantum Algorithms for Material Property Prediction
Fabrication of MEMS-Based Resonators for Sensing Applications
Cryogenic Measurement of Superconducting Junctions
Plasmonic Enhancement in Solar Energy Conversion Devices
Computational Study of Topological Insulators
Photodetector Optimization for Ultrafast Light Pulses
Analysis of Band Structures Using DFT Techniques
Nonlinear Magneto-Optical Kerr Effect in Thin Films
Laser Cooling of Trapped Atoms for Quantum Control
Design of Low-Noise Amplifiers for Space-Based Sensors
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