Unveiling prethermalization and thermal processes through the simplest one-dimensional topological model

TL;DR

This study investigates the thermalization process in a one-dimensional topological model, revealing stages of prethermalization and the influence of topological edge states on the dynamics.

Contribution

It introduces a detailed analysis of thermalization stages in a topological lattice, highlighting the role of edge states and factors affecting the process.

Findings

Thermalization occurs in three stages: out-of-equilibrium, prethermal, and final.

Topological edge states accelerate the thermalization process.

Prethermal states exist in both trivial and nontrivial regimes.

Abstract

Drawing on classical thermodynamic principles-such as the equipartition of energy and entropy maximization-extensive research has shown that the evolution of optical power in multimode optical systems tends toward a Rayleigh-Jeans distribution at thermal equilibrium. Understanding of the processes associated with the thermalization dynamics are of fundamental importance in analyzing and controlling such complex systems. In this work, we utilize a one-dimensional Su-Schrieffer-Heeger lattice as the simplest topological model to investigate the thermalization process of multiband systems in both topologically trivial and nontrivial regimes. Specifically, we identify that thermalization develops in three stages: (i) out-of-equilibrium dynamics, (ii) prethermal stage and (iii) final thermalization. Each individual band constitutes a subsystem that prethermalizes to the Rayleigh-Jeans distribution predicted from its power and internal energy. We find that this leads to a continuously varying prethermalization that eventually relaxes to the final thermal state (a dynamically evolving prethermal state). The presence of topological edge states can accelerate the thermalization process, although prethermal states exist both in the topologically trivial and nontrivial regimes. Factors such as bandgap width, temperature and nonlinearity that can influence the thermalization dynamics are examined in detail. Our work may offer valuable physical insights into understanding and controlling the thermalization process in multiband optical systems, paving the way for more efficient manipulation of light in complex settings.