Explore energy relaxation and dynamics in correlated metals through this 41-minute conference talk by N. Peter Armitage from Johns Hopkins University. Recorded as part of the "Electron Correlations beyond the Quasiparticle Paradigm: Theory and Experiment" conference at the Kavli Institute for Theoretical Physics, delve into cutting-edge research on materials that challenge the Fermi-liquid paradigm. Examine the latest theoretical and experimental results reshaping our understanding of quantum matter, including electron transport beyond quasiparticles, the Planckian limit on scattering, and Cooper pairing without quasiparticles. Gain insights into collective modes in systems lacking well-defined quasiparticles and recent advancements in quantum Monte Carlo simulations and numerical methods. Compare analytical results from low-energy theories with these computational approaches to further expand your knowledge of correlated metals and their complex behaviors.
Energy Relaxation and Dynamics in Correlated Metals - N. Peter Armitage (Johns Hopkins)
Kavli Institute for Theoretical Physics via YouTube
Overview
Syllabus
Energy relaxation and dynamics in correlated metals â–¸ N. Peter Armitage (Johns Hopkins)
Taught by
Kavli Institute for Theoretical Physics
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