Krylov Complexity of Fermionic and Bosonic Gaussian States

IF 5.6 3区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Fortschritte Der Physik-Progress of Physics Pub Date : 2024-03-15 DOI:10.1002/prop.202400014

Kiran Adhikari, Adwait Rijal, Ashok Kumar Aryal, Mausam Ghimire, Rajeev Singh, Christian Deppe

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Abstract

The concept of complexity has become pivotal in multiple disciplines, including quantum information, where it serves as an alternative metric for gauging the chaotic evolution of a quantum state. This paper focuses on Krylov complexity, a specialized form of quantum complexity that offers an unambiguous and intrinsically meaningful assessment of the spread of a quantum state over all possible orthogonal bases. This study is situated in the context of Gaussian quantum states, which are fundamental to both Bosonic and Fermionic systems and can be fully described by a covariance matrix. While the covariance matrix is essential, it is insufficient alone for calculating Krylov complexity due to its lack of relative phase information is shown. The relative covariance matrix can provide an upper bound for Krylov complexity for Gaussian quantum states is suggested. The implications of Krylov complexity for theories proposing complexity as a candidate for holographic duality by computing Krylov complexity for the thermofield double States (TFD) and Dirac field are also explored.

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费米子和玻色高斯态的克雷洛夫复杂性

复杂性的概念在包括量子信息在内的多个学科中已变得举足轻重，它是衡量量子态混乱演化的另一种度量标准。本文的重点是克雷洛夫复杂性，它是量子复杂性的一种特殊形式，可对量子态在所有可能的正交基上的扩散情况进行明确且具有内在意义的评估。这项研究以高斯量子态为背景，高斯量子态是玻色子和费米子系统的基本量子态，可以用协方差矩阵来完全描述。虽然协方差矩阵至关重要，但由于缺乏相对相位信息，它不足以单独计算克雷洛夫复杂性。相对协方差矩阵可以为高斯量子态的克雷洛夫复杂度提供一个上限。通过计算热场双态（TFD）和狄拉克场的克雷洛夫复杂性，还探讨了克雷洛夫复杂性对提出复杂性作为全息对偶性候选者的理论的影响。

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

Fortschritte Der Physik-Progress of Physics 物理-物理：综合

CiteScore

6.70

自引率

7.70%

发文量

审稿时长

6-12 weeks

期刊介绍： The journal Fortschritte der Physik - Progress of Physics is a pure online Journal (since 2013). Fortschritte der Physik - Progress of Physics is devoted to the theoretical and experimental studies of fundamental constituents of matter and their interactions e. g. elementary particle physics, classical and quantum field theory, the theory of gravitation and cosmology, quantum information, thermodynamics and statistics, laser physics and nonlinear dynamics, including chaos and quantum chaos. Generally the papers are review articles with a detailed survey on relevant publications, but original papers of general interest are also published.