Signatures of dissipative quantum chaos

TL;DR

This paper explores the universal signatures of chaos in dissipative quantum systems, combining non-Hermitian random matrix theory and symmetry analysis to understand their dynamics, steady states, and classification.

Contribution

It introduces a unified framework for analyzing chaos in open quantum systems, integrating non-Hermitian random matrices and symmetry classification for dissipative quantum matter.

Findings

Relaxation timescales and steady states characterized for various dissipative models

Classification of dissipative quantum systems based on symmetry and universality

Framework applicable to complex quantum structures with potential technological impact

Abstract

Understanding the far-from-equilibrium dynamics of dissipative quantum systems, where dissipation and decoherence coexist with unitary dynamics, is an enormous challenge with immense rewards. Often, the only realistic approach is to forgo a detailed microscopic description and search for signatures of universal behavior shared by collections of many distinct, yet sufficiently similar, complex systems. Quantum chaos provides a powerful statistical framework for addressing this question, relying on symmetries to obtain information not accessible otherwise. This thesis examines how to reconcile chaos with dissipation, proceeding along two complementary lines. In Part I, we apply non-Hermitian random matrix theory to open quantum systems with Markovian dissipation and discuss the relaxation timescales and steady states of three representative examples of increasing physical relevance: single-particle Lindbladians and Kraus maps, open free fermions, and dissipative Sachdev-Ye-Kitaev (SYK) models. In Part II, we investigate the symmetries, correlations, and universality of many-body open quantum systems, classifying several models of dissipative quantum matter. From a theoretical viewpoint, this thesis lays out a generic framework for the study of the universal properties of realistic, chaotic, and dissipative quantum systems. From a practical viewpoint, it provides the concrete building blocks of dynamical dissipative evolution constrained by symmetry, with potential technological impact on the fabrication of complex quantum structures. (Full abstract in the thesis.)