![]() ![]() Among the courses that Schwartz has taught: Earth Science, Geochemistry, and Natural Disasters. His findings have been published in books and in journals such as Biogeosciences, Estuaries and Coasts, and Limnology and Oceanography. Much of his research has involved local waters – Choctawhatchee Bay, Pensacola Bay and Santa Rosa Sound, among others - and the Gulf Islands National Seashore. in Marine Studies – Oceanography at the University of Delaware and held two postdoctoral fellowships before he joined UWF in 2005. ![]() ![]() Schwartz is not currently accepting new graduate research students. Due to his current administrative assignment with UWF, Dr. Schwartz’s research covers many aspects of estuarine biogeochemistry: red tide harmful algal blooms, submarine groundwater discharges into estuarine and coastal waters, and methods used to evaluate biogeochemical processes, to name three examples. His work on modern machine learning exploits state-of-the-art developments in computer science to reshape the frontiers of particle physics.Matthew Schwartz, who has taught undergraduate and graduate courses in Geology, Hydrology and related topics, is a Professor in the Department of Earth and Environmental Sciences as well as the Assistant Vice President of Research Administration. For example, he has demonstrated the efficacy of convolutional networks both for complex discrimination and for regression tasks relevant to the Large Hadron Collider. Recently, Schwartz has been bringing machine learning techniques to bear on collider physics problems. He has produced the first viable methods for finding highly energetic top quarks, measuring the electric charge of quark jets, discriminating quarks from gluons, measuring color flow, and removing contamination from secondary hadronic collsions. Schwartz has produced the world's most precise calculation of a number of observables, including event and jet shapes. To make progress in this direction, Schwartz has brought new tools to bear on old problems, such as exploiting hidden symmetries associated with broken scale or Lorentz invariance, or ideas from effective field theory.Īnother theme in Schwartz's research is developing new methods for precision calculations and new physics searches at colliders. ![]() A third example comprises factorization-violating effects associated with strong coupling in gauge theories. Another example is the instanton calculus, which Schwartz has developed for tunneling calculations in quantum field theory, producing new insights into the ultimate fate of our universe. An example of this is the effective field theory approach, which Schwartz has advanced and applied in many contexts. A key observation is that non-perturbative effects can be calculable if the expansion is reorganized in a clever way. Press, 2013) is a standard text adopted in field theory courses worldwide.Ī central element of Schwartz's current research is how perturbation theory can be used to explain non-perturbative physics. His textbook Quantum Field Theory and the Standard Model (Cambridge Univ. Schwartz has contributed to diverse realms of particle physics, from quantum gravity to quantum chromodynamics. This includes exploring the foundations and structure of quantum field theories, improving our ability to perform precision calculations in the Standard Model, and developing new methods for collider physics. Matthew Schwartz's research is focused on expanding the boundaries of our current understanding of particle physics. ![]()
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |