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Main Authors: Miyaji, Masamichi, Ruan, Shan-Ming, Shibuya, Shono, Yano, Kazuyoshi
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2507.23667
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author Miyaji, Masamichi
Ruan, Shan-Ming
Shibuya, Shono
Yano, Kazuyoshi
author_facet Miyaji, Masamichi
Ruan, Shan-Ming
Shibuya, Shono
Yano, Kazuyoshi
contents Holographic complexity, as the bulk dual of quantum complexity, encodes the geometric structure of black hole interiors. Motivated by the complexity=anything proposal, we introduce the spectral representation for generating functions associated with codimension-one and codimension-zero holographic complexity measures. These generating functions exhibit a universal slope-ramp-plateau structure, analogous to the spectral form factor in chaotic quantum systems. In such systems, quantum complexity evolves universally, displaying long-time linear growth followed by saturation at late times. By employing the generating function formalism, we demonstrate that this universal behavior originates from random matrix universality in spectral statistics and from a particular pole structure of the matrix elements of the generating functions in the energy eigenbasis. Using the residue theorem, we prove that the existence of this pole structure is both a necessary and sufficient condition for the linear growth of complexity measures. Furthermore, we show that the late-time saturation plateau arises directly from the spectral level repulsion, a hallmark of quantum chaos.
format Preprint
id arxiv_https___arxiv_org_abs_2507_23667
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Universal Time Evolution of Holographic and Quantum Complexity
Miyaji, Masamichi
Ruan, Shan-Ming
Shibuya, Shono
Yano, Kazuyoshi
High Energy Physics - Theory
General Relativity and Quantum Cosmology
Holographic complexity, as the bulk dual of quantum complexity, encodes the geometric structure of black hole interiors. Motivated by the complexity=anything proposal, we introduce the spectral representation for generating functions associated with codimension-one and codimension-zero holographic complexity measures. These generating functions exhibit a universal slope-ramp-plateau structure, analogous to the spectral form factor in chaotic quantum systems. In such systems, quantum complexity evolves universally, displaying long-time linear growth followed by saturation at late times. By employing the generating function formalism, we demonstrate that this universal behavior originates from random matrix universality in spectral statistics and from a particular pole structure of the matrix elements of the generating functions in the energy eigenbasis. Using the residue theorem, we prove that the existence of this pole structure is both a necessary and sufficient condition for the linear growth of complexity measures. Furthermore, we show that the late-time saturation plateau arises directly from the spectral level repulsion, a hallmark of quantum chaos.
title Universal Time Evolution of Holographic and Quantum Complexity
topic High Energy Physics - Theory
General Relativity and Quantum Cosmology
url https://arxiv.org/abs/2507.23667