Litcius/Paper detail

Hilbert space fragmentation produces an effective attraction between fractons

Xiaozhou Feng, Brian Skinner

2022Physical Review Research25 citationsDOIOpen Access PDF

Abstract

Fracton systems exhibit restricted mobility of their excitations due to the presence of higher-order conservation laws. Here we study the time evolution of a one-dimensional fracton system with charge and dipole moment conservation using a random unitary circuit description. Previous work has shown that when the random unitary operators act on four or more sites, an arbitrary initial state eventually thermalizes via a universal subdiffusive dynamics. In contrast, a system evolving under three-site gates fails to thermalize due to strong "fragmentation" of the Hilbert space. Here we show that three-site gate dynamics causes a given initial state to evolve toward a highly nonthermal state on a timescale consistent with Brownian diffusion. Strikingly, the dynamics produces an effective attraction between isolated fractons or between a single fracton and the boundaries of the system, as in the Casimir effect of quantum electrodynamics. We show how this attraction can be understood by exact mapping to a simple classical statistical mechanics problem, which we solve exactly for the case of an initial state with either one or two fractons.

Topics & Concepts

FractonPhysicsUnitary stateStatistical physicsHilbert spaceStatistical mechanicsVon Neumann architectureClassical mechanicsQuantum mechanicsTheoretical physicsMathematicsMathematical analysisPure mathematicsPolitical scienceLawFractalQuantum many-body systemsQuantum and electron transport phenomenaQuantum Computing Algorithms and Architecture