Semiclassical limit for the many-body localization transition Article Swipe

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Semiclassical physics Limit (mathematics) Ergodic theory Floquet theory Delocalized electron Physics Boundary (topology) Fermion Quasiperiodicity Quantum mechanics Mathematical physics Classical mechanics Mathematics Quasiperiodic function Mathematical analysis Condensed matter physics Quantum Nonlinear system

Anushya Chandran , Chris R. Laumann ·

YOU? · · 2015 · Open Access · · DOI: https://doi.org/10.1103/physrevb.92.024301 · OA: W2257642323

We introduce a semi-classical limit for many-body localization in the absence of global symmetries. Microscopically, this limit is realized by disordered Floquet circuits composed of Clifford gates. In $d=1$, the resulting dynamics are always many-body localized with a complete set of strictly local integrals of motion. In $d\geq 2$, the system realizes both localized and delocalized phases separated by a continuous transition in which ergodic puddles percolate. We argue that the phases are stable to deformations away from the semi-classical limit and estimate the resulting phase boundary. The Clifford circuit model is a distinct tractable limit from that of free fermions and suggests bounds on the critical exponents for the generic transition.