Transport in the sine-Gordon field theory: From generalized hydrodynamics to semiclassics

Physical Review B American Physical Society (APS) 100:3 (2019) 035108

Authors:

Bruno Bertini, Lorenzo Piroli, Márton Kormos

Bose-Einstein-like condensation in scalar active matter with diffusivity edge

Physical Review E American Physical Society (APS) 100:1 (2019) 010601

Exact solution of a percolation analog for the many-body localization transition

Physical Review Letters American Physical Society 99:22 (2019) 99

Authors:

Sthitadhi Roy, David Logan, John Chalker

Abstract:

We construct and solve a classical percolation model with a phase transition that we argue acts as a proxy for the quantum many-body localization transition. The classical model is defined on a graph in the Fock space of a disordered, interacting quantum spin chain, using a convenient choice of basis. Edges of the graph represent matrix elements of the spin Hamiltonian between pairs of basis states that are expected to hybridize strongly. At weak disorder, all nodes are connected, forming a single cluster. Many separate clusters appear above a critical disorder strength, each typically having a size that is exponentially large in the number of spins but a vanishing fraction of the Fock-space dimension. We formulate a transfer matrix approach that yields an exact value ν = 2 for the localization length exponent, and also use complete enumeration of clusters to study the transition numerically in finite-sized systems.

Partial Equilibration of the Anti-Pfaffian edge due to Majorana Disorder

(2019)

Authors:

Steven H Simon, Bernd Rosenow

Eigenstate correlations, thermalization, and the butterfly effect

Physical Review Letters American Physical Society 122:22 (2019) 220601

Authors:

Amos Chan, Andrea De Luca, John Chalker

Abstract:

We discuss eigenstate correlations for ergodic, spatially extended many-body quantum systems, in terms of the statistical properties of matrix elements of local observables. While the eigenstate thermalization hypothesis (ETH) is known to give an excellent description of these quantities, the phenomenon of scrambling and the butterfly effect imply structure beyond ETH. We determine the universal form of this structure at long distances and small eigenvalue separations for Floquet systems. We use numerical studies of a Floquet quantum circuit to illustrate both the accuracy of ETH and the existence of our predicted additional correlations.