Complexity of energy eigenstates as a mechanism for equilibration

Understanding the mechanisms responsible for the equilibration of isolated quantum many-body systems is a long-standing open problem. In this work we obtain a statistical relationship between the equilibration properties of Hamiltonians and the complexity of their eigenvectors, provided that a conje...

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Detalles Bibliográficos
Autores principales: Masanes, L., Roncaglia, A.J., Acín, A.
Formato: JOUR
Materias:
Complexity theory
Energy eigenstates
Equilibration time
Level density
Quantum circuit
Quantum many-body systems
Statistical relationship
System size
Eigenvalues and eigenfunctions
Logic circuits
Quantum theory
Hamiltonians
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_15393755_v87_n3_p_Masanes
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_15393755_v87_n3_p_Masanes
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spelling todo:paper_15393755_v87_n3_p_Masanes2023-10-03T16:22:45Z Complexity of energy eigenstates as a mechanism for equilibration Masanes, L. Roncaglia, A.J. Acín, A. Complexity theory Energy eigenstates Equilibration time Level density Quantum circuit Quantum many-body systems Statistical relationship System size Eigenvalues and eigenfunctions Logic circuits Quantum theory Hamiltonians Understanding the mechanisms responsible for the equilibration of isolated quantum many-body systems is a long-standing open problem. In this work we obtain a statistical relationship between the equilibration properties of Hamiltonians and the complexity of their eigenvectors, provided that a conjecture about the incompressibility of quantum circuits holds. We quantify the complexity by the size of the smallest quantum circuit mapping the local basis onto the energy eigenbasis. Specifically, we consider the set of all Hamiltonians having complexity C, and show that almost all such Hamiltonians equilibrate if C is superquadratic in the system size, which includes the fully random Hamiltonian case in the limit C→∞, and do not equilibrate if C is sublinear. We also provide a simple formula for the equilibration time scale in terms of the Fourier transform of the level density. Our results are statistical and, therefore, do not apply to specific Hamiltonians. Yet they establish a fundamental link between equilibration and complexity theory. © 2013 American Physical Society. Fil:Roncaglia, A.J. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_15393755_v87_n3_p_Masanes
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Complexity theory
Energy eigenstates
Equilibration time
Level density
Quantum circuit
Quantum many-body systems
Statistical relationship
System size
Eigenvalues and eigenfunctions
Logic circuits
Quantum theory
Hamiltonians
spellingShingle Complexity theory
Energy eigenstates
Equilibration time
Level density
Quantum circuit
Quantum many-body systems
Statistical relationship
System size
Eigenvalues and eigenfunctions
Logic circuits
Quantum theory
Hamiltonians
Masanes, L.
Roncaglia, A.J.
Acín, A.
Complexity of energy eigenstates as a mechanism for equilibration
topic_facet Complexity theory
Energy eigenstates
Equilibration time
Level density
Quantum circuit
Quantum many-body systems
Statistical relationship
System size
Eigenvalues and eigenfunctions
Logic circuits
Quantum theory
Hamiltonians
description Understanding the mechanisms responsible for the equilibration of isolated quantum many-body systems is a long-standing open problem. In this work we obtain a statistical relationship between the equilibration properties of Hamiltonians and the complexity of their eigenvectors, provided that a conjecture about the incompressibility of quantum circuits holds. We quantify the complexity by the size of the smallest quantum circuit mapping the local basis onto the energy eigenbasis. Specifically, we consider the set of all Hamiltonians having complexity C, and show that almost all such Hamiltonians equilibrate if C is superquadratic in the system size, which includes the fully random Hamiltonian case in the limit C→∞, and do not equilibrate if C is sublinear. We also provide a simple formula for the equilibration time scale in terms of the Fourier transform of the level density. Our results are statistical and, therefore, do not apply to specific Hamiltonians. Yet they establish a fundamental link between equilibration and complexity theory. © 2013 American Physical Society.
format JOUR
author Masanes, L.
Roncaglia, A.J.
Acín, A.
author_facet Masanes, L.
Roncaglia, A.J.
Acín, A.
author_sort Masanes, L.
title Complexity of energy eigenstates as a mechanism for equilibration
title_short Complexity of energy eigenstates as a mechanism for equilibration
title_full Complexity of energy eigenstates as a mechanism for equilibration
title_fullStr Complexity of energy eigenstates as a mechanism for equilibration
title_full_unstemmed Complexity of energy eigenstates as a mechanism for equilibration
title_sort complexity of energy eigenstates as a mechanism for equilibration
url http://hdl.handle.net/20.500.12110/paper_15393755_v87_n3_p_Masanes
work_keys_str_mv AT masanesl complexityofenergyeigenstatesasamechanismforequilibration
AT roncagliaaj complexityofenergyeigenstatesasamechanismforequilibration
AT acina complexityofenergyeigenstatesasamechanismforequilibration
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