Litcius/Paper detail

Quantum phase transition of many interacting spins coupled to a bosonic bath: Static and dynamical properties

G. De Filippis, A. de Candia, А. S. Mishchenko, Loris Maria Cangemi, Alberto Nocera, Petr A. Mishchenko, Maura Sassetti, Rosario Fazio, Naoto Nagaosa, V. Cataudella

2021Physical review. B./Physical review. B14 citationsDOIOpen Access PDF

Abstract

By using worldline and diagrammatic quantum Monte Carlo techniques, matrix product state, and a variational approach \`a la Feynman, we investigate the equilibrium properties and relaxation features of a quantum system of $N$ spins antiferromagnetically interacting with each other, with strength $J$, and coupled to a common bath of bosonic oscillators, with strength $\ensuremath{\alpha}$. We show that, in the Ohmic regime, a Beretzinski-Thouless-Kosterlitz quantum phase transition occurs. While for $J=0$ the critical value of $\ensuremath{\alpha}$ decreases asymptotically with $1/N$ by increasing $N$, for nonvanishing $J$ it turns out to be practically independent on $N$, allowing to identify a finite range of values of $\ensuremath{\alpha}$ where spin phase coherence is preserved also for large $N$. Then, by using matrix product state simulations, and the Mori formalism and the variational approach \`a la Feynman jointly, we unveil the features of the relaxation, that, in particular, exhibits a nonmonotonic dependence on the temperature reminiscent of the Kondo effect. For the observed quantum phase transition we also establish a criterion analogous to that of the metal-insulator transition in solids.

Topics & Concepts

PhysicsSpinsMatrix product stateQuantum phase transitionQuantum mechanicsQuantumFeynman diagramPhase transitionQuantum Monte CarloCondensed matter physicsMonte Carlo methodQuantum entanglementMathematicsStatisticsPhysics of Superconductivity and MagnetismQuantum and electron transport phenomenaQuantum many-body systems