Flatiron Research Fellow, Center for Computational Quantum Physics, Simons Foundation Flatiron Institute (2017-2020)
- Ph.D. Physics, Stanford University (2017)
- M.Sc. Electrical Engineering, ETH Zurich (2009)
My research focuses on the theory of non-equilibrium dynamics and correlated phases in quantum materials – a class of materials with emergent properties that arise from the collective behavior of electrons. Driven by rapid advances in time-resolved experiments, an exciting frontier is the possibility to use external driving such as strong optical pulses to push such materials into non-equilibrium states with novel and useful properties. This poses numerous new and interesting problems: for instance, an interacting quantum system far from equilibrium can in principle exhibit markedly different dynamics when probed on different time scales or possess properties that fundamentally cannot be realized in a conventional solid. My research aims to understand how materials properties, light, and electronic interactions or topology can conspire to realize new states of matter far from equilibrium, and tackles these questions using theoretical techniques and numerical simulations. Recent interests include many-body Floquet states, topological phases, thermalization and dissipation, ultrafast dynamics, and correlated phenomena in two-dimensional Moiré heterostructures of van der Waals materials.
- D. M. Kennes, L. Xian, M. Claassen, and A. Rubio, “A New Twist in the Realization of One-Dimensional Physics”, Nature Comm. 11, 1124 (2020).
- M. Claassen, D. M. Kennes, M. Zingl, M. A. Sentef, and A. Rubio, “Universal Optical Control of Chiral Superconductors and Majorana Modes”, Nature Physics 15, 766 (2019).
- Y. Wang, M. Claassen, C. D. Pemmaraju, C. Jia, B. Moritz, and T. P. Devereaux, “Theoretical Understanding of Photon Spectroscopies in Correlated Materials In and Out of Equilibrium”, Nature Rev. Mater. 3, 312 (2018).
- M. Claassen, H.-C. Jiang, B. Moritz, and T. P. Devereaux, “Dynamical Time-Reversal Symmetry Breaking and Photo-Induced Chiral Spin Liquid in Frustrated Mott Insulators”, Nature Comm. 8, 1192 (2017).
- M. Claassen, C. Jia, B. Moritz, and T. P. Devereaux, “All-Optical Materials Design of Chiral Edge Modes in Transition-Metal Dichalcogenides”, Nature Comm. 7, 13074 (2016).
- M. Claassen, C. H. Lee, R. Thomale, X.-L. Qi, and T. P. Devereaux, “Position-Momentum Duality and Fractional Quantum Hall Effect in Chern Insulators”, Phys. Rev. Lett. 114, 236802 (2015).