Condensed Matter Theory

Exact solution of a percolation analogue for the many-body localisation transition

(2018)

Authors:

Sthitadhi Roy, David E Logan, JT Chalker

Topological states in chiral active matter: dynamic blue phases and active half-skyrmions

(2018)

Authors:

Luuk Metselaar, Amin Doostmohammadi, Julia M Yeomans

Sustained oscillations of epithelial cell sheets

Cold Spring Harbor Laboratory (2018) 492082

Authors:

Grégoire Peyret, Romain Mueller, Joseph d’Alessandro, Simon Begnaud, Philippe Marcq, René-Marc Mège, Julia M Yeomans, Amin Doostmohammadi, Benoît Ladoux

Exotic criticality in the dimerized spin-1 $XXZ$ chain with single-ion anisotropy

SciPost Physics Stichting SciPost 5:6 (2018) 059

Authors:

Satoshi Ejima, Tomoki Yamaguchi, Fabian Essler, Florian Lange, Yukinori Ohta, Holger Fehske

Abstract:

We consider the dimerized spin-1 XXZ chain with single-ion anisotropy D. In absence of an explicit dimerization there are three phases: a large-$D$, an antiferromagnetically ordered and a Haldane phase. This phase structure persists up to a critical dimerization, above which the Haldane phase disappears. We show that for weak dimerization the phases are separated by Gaussian and Ising quantum phase transitions. One of the Ising transitions terminates in a critical point in the universality class of the dilute Ising model. We comment on the relevance of our results to experiments on quasi-one-dimensional anisotropic spin-1 quantum magnets.

Mott, Floquet, and the response of periodically driven Anderson insulators

Physical Review B 98:21 (2018)

Authors:

DT Liu, JT Chalker, V Khemani, SL Sondhi

Abstract:

© 2018 American Physical Society. We consider periodically driven Anderson insulators. The short-time behavior for weak, monochromatic, uniform electric fields is given by linear response theory and was famously derived by Mott. We go beyond this to consider both long times - which is the physics of Floquet late time states - and strong electric fields. This results in a "phase diagram" in the frequency-field strength plane, in which we identify four distinct regimes. These are a linear response regime dominated by preexisting Mott resonances, which exists provided Floquet saturation is not reached within a period; a nonlinear perturbative regime, which exhibits multiphoton-absorption in response to the field; a near-adiabatic regime, which exhibits a primarily reactive response spread over the entire sample and is insensitive to preexisting resonances; and finally an enhanced dissipative regime.