Michael Sekatchev
Student
Master of Science in Physics (MSc)
Physics
Physics provides research opportunities in many subfields of physics, including
- applied physics: this effort has spawned a number of spin-off companies.
- medical physics: be involved in a broad range of medical physics research in the areas of radiation therapy, medical imaging, biomedical optics and radiation biophysics.
- biophysics: the application of quantitative principles and methods to biological systems.
- nuclear and particle physics: the aim of subatomic physics is to understand matter and the fundamental forces in the universe and ultimately form a Theory of Everything.
- astronomy and astrophysics: study stars, galaxies, the material in between, and the Universe as a whole.
- atomic, molecular, and optical physics: this field is rapidly expanding and serves as the basis for many modern technological innovations.
- condensed matter physics is concerned with understanding and exploiting the properties of solids and liquids and the large area that this covers makes it the largest field of contemporary physics.
- theoretical physics: Gravity and Relativity, String Theory, High Energy Physics, and Condensed Matter Theory, to Quantum Information and Biophysics
Explore our Programs in Physics
Faculty Members in Physics
| Name | Research Interests |
|---|---|
| Aronson, Meigan | heavy-ferromagnetic compounds; charge density waves; magnetic nanoparticles; Charge density waves, Heavy-ferromagnetic compounds, Magnetic nanoparticles |
| Berciu, Mona | condensed matter theory; polarons, bipolarons; strongly correlated systems; Condensed matter theory, Polarons, bipolarons, Strongly correlated systems |
| Boley, Aaron | Astronomy and Astrophysics; Planet formation, protoplanetary disk evolution, formation of meteorite parent bodies |
| Bryman, Douglas | Experimental Particle Physics; Applied physics; physics; Experimental Particle Physics, Applied physics, Physics |
| Burke, Sarah | Scanning probe microscopy, organic materials, nanoscale materials, surface physics, photovoltaics |
| Choptuik, Matthew | Theoretical physics, Relativity/Computational Physics |
| Damascelli, Andrea | Electronic Structure of Quantum Materials; Electronic Structure of Quantum Materials |
| Dierker, Steve | Collective dynamics of condensed matter systems; Dependence on reduced dimensionality, strong interactions, disorder, and mesoscale structure; Collective dynamics of condensed matter systems, Dependence on reduced dimensionality, strong interactions, disorder, and mesoscale structure |
| Folk, Joshua | 2D materials and Vanderwaals heterostructures; Quantum electronics; Thermodynamics of quantum systems; Strongly correlated phenomena; Topological phenomena; Quantum transport; 2D materials and Vanderwaals heterostructures, Quantum electronics, Thermodynamics of quantum systems, Strongly correlated phenomena, Topological phenomena, Quantum transport |
| Franz, Marcel | Condensed matter theory |
| Gay, Colin | Experimental subatomic physics, Beyond Standard Model physics, Extra dimensions |
| Gladman, Brett | Astronomy, Planetary Science, meteorites, astrobiology, Solar system formation and evolution |
| Hallas, Alannah | Quantum materials; Materials design and discovery; magnetism; Disorder; superconductivity; Quantum materials, Materials design and discovery, Magnetism, Disorder, Superconductivity |
| Halpern, Mark | Cosmology, Cosmic background radiation, history of star formation, measuring the geometry and contents of the Universe, satellites, balloon-borne telescopes, the physics of music, Physics of music, Cosmic Microwave Background, Physical Cosmology, Star formation history |
| Hasinoff, Michael | Low-energy particle physics |
| Hearty, Christopher | Experimental Particle Physics; e+e- collider; Physics beyond the Standard Model; Dark sector; dark matter; Experimental particle physics , e+e- collider, Physics beyond the Standard Model, Dark sector, Dark matter |
| Heyl, Jeremy | Astrophysics; Black Holes; Neutron Stars; quantum phenomena; Quantum-Field Theory; Stellar; Stellar Physics; Astrophysics, Black Holes, Neutron Stars, Quantum Phenomena, Quantum-Field Theory, Stellar, Stellar Physics |
| Hinshaw, Gary | cosmology, cosmic background radiation, Cosmology, Measuring diffuse background radiations |
| Jones, David | Atomic, optical and molecular physics,Ultrafast Optics, Spectroscopy |
| Karczmarek, Joanna | Emergent spacetime and gravity; Matrix models; Noncommutative geometry; String theory; Emergent spacetime and gravity, Matrix models, Noncommutative geometry, String theory |
| Kunimoto, Michelle | exoplanet detection, characterization, and demographics; exoplanet detection, characterization, and demographics |
| Leslie, Sabrina | |
| Lister, Alison | Large Hadron Collier (LHC); ATLAS experiment; Search for physics beyond the standard model; top quarks; dark matter; Machine Learning; Long-lived particles; Large Hadron Collier (LHC), ATLAS experiment, Search for physics beyond the standard model, top quarks, Dark Matter, Machine Learning, Long-lived particles |
| Madison, Kirk | Quantum sensors; Quantum Gases; Laser cooling; Bose-Einstein Condesation; Fermi-Degenerate Gases; Quantum optics; Laser physics; Quantum sensors, Quantum Gases, Laser cooling, Bose-Einstein Condesation, Fermi-Degenerate Gases, Quantum optics, Laser physics |
| Marziali, Andre | Teaching methods, pedagogy, Robotics in education, Nanotechnology, Engineering Physics, Genomics, Biophysics, Genomics Technologies |