Scrambling Dynamics and Out-of-Time Ordered Correlators in Quantum Many-Body Systems: a Tutorial

TL;DR

This tutorial explains quantum information scrambling in many-body systems, focusing on out-of-time ordered correlators (OTOCs), their theoretical foundations, computational methods, and experimental measurement techniques.

Contribution

It provides a comprehensive framework for understanding, calculating, and measuring quantum information scrambling and OTOCs in complex quantum systems.

Findings

OTOCs can be analytically computed in toy models like SYK and random circuits.

Numerical methods such as exact diagonalization and tensor networks are effective for OTOC calculation.

Experimental schemes for measuring OTOC are actively being developed and surveyed.

Abstract

This tutorial article introduces the physics of quantum information scrambling in quantum many-body systems. The goals are to understand how to precisely quantify the spreading of quantum information and how causality emerges in complex quantum systems. We introduce a general framework to study the dynamics of quantum information, including detection and decoding. We show that the dynamics of quantum information is closely related to operator dynamics in the Heisenberg picture, and, under certain circumstances, can be precisely quantified by the so-called out-of-time ordered correlator~(OTOC). The general behavior of OTOC is discussed based on several toy models, including the Sachdev-Ye-Kitaev model, random circuit models, and Brownian models, in which OTOC is analytically tractable. We introduce numerical methods, including exact diagonalization and tensor network methods, to calculate OTOC for generic quantum many-body systems. We also survey current experimental schemes for measuring OTOC in various quantum simulators.