Krylov complexity and Trotter transitions in unitary circuit dynamics

IF 3.7 2区物理与天体物理 Q1 Physics and Astronomy

Physical Review B Pub Date : 2025-01-15 DOI:10.1103/physrevb.111.014309

Philippe Suchsland, Roderich Moessner, Pieter W. Claeys

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引用次数: 0

Abstract

We investigate many-body dynamics where the evolution is governed by unitary circuits through the lens of “Krylov complexity,” a recently proposed measure of complexity and quantum chaos. We extend the formalism of Krylov complexity to unitary circuit dynamics and focus on Floquet circuits arising as the Trotter decomposition of Hamiltonian dynamics. For short Trotter steps the results from Hamiltonian dynamics are recovered, whereas a large Trotter step results in different universal behavior characterized by the existence of local : operators with vanishing autocorrelation functions, as exemplified in dual-unitary circuits. These operators exhibit maximal complexity growth, act as a memoryless bath for the dynamics, and can be directly probed in current quantum computing setups. These two regimes are separated by a crossover in chaotic systems. Conversely, we find that free integrable systems exhibit a nonanalytic transition between these different regimes, where maximally ergodic operators appear at a critical Trotter step.

Published by the American Physical Society

2025

查看原文本刊更多论文

单位电路动力学中的Krylov复杂度和Trotter转换

我们通过“克里洛夫复杂性”（最近提出的一种复杂性和量子混沌的测量方法）的镜头，研究由单一电路控制的多体动力学。我们将Krylov复杂度的形式主义扩展到幺正电路动力学，并重点研究了由哈密顿动力学的Trotter分解而产生的Floquet电路。对于较短的Trotter步长，哈密顿动力学的结果是恢复的，而较大的Trotter步长会导致不同的普遍行为，其特征是存在自相关函数消失的局部算子，如双幺正电路中的例子。这些运算符表现出最大的复杂性增长，充当动力学的无记忆浴，并且可以在当前的量子计算设置中直接探测。在混沌系统中，这两种状态被交叉区分开。相反，我们发现自由可积系统在这些不同的区域之间表现出非解析转换，其中最大遍历算子出现在关键的Trotter步上。2025年由美国物理学会出版

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physical Review B 物理-物理：凝聚态物理

CiteScore

6.70

自引率

32.40%

发文量

审稿时长

3.0 months

期刊介绍： Physical Review B (PRB) is the world’s largest dedicated physics journal, publishing approximately 100 new, high-quality papers each week. The most highly cited journal in condensed matter physics, PRB provides outstanding depth and breadth of coverage, combined with unrivaled context and background for ongoing research by scientists worldwide. PRB covers the full range of condensed matter, materials physics, and related subfields, including: -Structure and phase transitions -Ferroelectrics and multiferroics -Disordered systems and alloys -Magnetism -Superconductivity -Electronic structure, photonics, and metamaterials -Semiconductors and mesoscopic systems -Surfaces, nanoscience, and two-dimensional materials -Topological states of matter