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Typical thermalization of low-entanglement states

Published 26 Mar 2024 in quant-ph, cond-mat.stat-mech, math-ph, and math.MP | (2403.18007v4)

Abstract: Proving thermalization from the unitary evolution of a closed quantum system is one of the oldest questions that is still nowadays only partially resolved. Several efforts have led to various formulations of what is called the eigenstate thermalization hypothesis, which leads to thermalization under certain conditions on the initial states. These conditions, however, are sensitive to the precise formulation of the hypothesis. In this work, we focus on the important case of low entanglement initial states, which are operationally accessible in many natural physical settings, including experimental schemes for testing thermalization and for quantum simulation. We prove thermalization of these states under precise conditions that have operational significance. More specifically, motivated by arguments of unavoidable finite resolution, we define a random energy smoothing on local Hamiltonians that leads to local thermalization when the initial state has low entanglement. Finally we show that such a transformation affects neither the Gibbs state locally nor, under generic smoothness conditions on the spectrum, the short-time dynamics.

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References (24)
  1. J. v. Neumann, Beweis des Ergodensatzes und des H-Theorems in der neuen Mechanik, Z. Phys. 57, 30 (1929).
  2. E. T. Jaynes, Information theory and statistical mechanics, Phys. Rev. 106, 620 (1957a).
  3. E. T. Jaynes, Information theory and statistical mechanics. ii, Phys. Rev. 108, 171 (1957b).
  4. J. Eisert, M. Friesdorf, and C. Gogolin, Quantum many-body systems out of equilibrium, Nature Phys. 11, 124 (2015).
  5. M. Srednicki, Chaos and quantum thermalization, Phys. Rev. E 50, 888 (1994).
  6. J. M. Deutsch, Eigenstate thermalization hypothesis, Rep. Prog. Phys. 81, 082001 (2018).
  7. P. W. Anderson, Absence of diffusion in certain random lattices, Phys. Rev. 109, 1492 (1958).
  8. S. Popescu, A. J. Short, and A. Winter, Entanglement and the foundations of statistical mechanics, Nature Phys. 2, 754 (2006).
  9. M. Cramer, Thermalization under randomized local Hamiltonians,  14, 053051 (2012).
  10. P. Reimann, Typical fast thermalization processes in closed many-body systems, Nature Comm. 7, 10821 (2016).
  11. L. Dabelow, P. Vorndamme, and P. Reimann, Thermalization of locally perturbed many-body quantum systems, Phys. Rev. B 105, 024310 (2022).
  12. J. H. Bardarson, F. Pollmann, and J. E. Moore, Unbounded growth of entanglement in models of many-body localization, Phys. Rev. Lett. 109, 017202 (2012).
  13. I. H. Kim, A. Chandran, and D. A. Abanin, Local integrals of motion and the logarithmic lightcone in many-body localized systems (2014), arXiv:1412.3073 .
  14. R. Singh, J. H. Bardarson, and F. Pollmann, Signatures of the many-body localization transition in the dynamics of entanglement and bipartite fluctuations,  18, 023046 (2016).
  15. F. G. S. L. Brandao and M. Cramer, Equivalence of statistical mechanical ensembles for non-critical quantum systems (2015), arXiv:1502.03263 .
  16. A. J. Short and T. C. Farrelly, Quantum equilibration in finite time,  14, 013063 (2012).
  17. P. Reimann and M. Kastner, Equilibration of isolated macroscopic quantum systems,  14, 043020 (2012).
  18. T. Farrelly, F. G. Brandão, and M. Cramer, Thermalization and return to equilibrium on finite quantum lattice systems, Phys. Rev. Lett. 118, 140601 (2017).
  19. H. Araki, Gibbs states of a one dimensional quantum lattice, Commun. Math. Phys. 14, 120 (1969).
  20. A. M. Alhambra, Quantum many-body systems in thermal equilibrium, PRX Quantum 4, 040201 (2023).
  21. K. S. Rai, J. I. Cirac, and A. M. Alhambra, Matrix product state approximations to quantum states of low energy variance (2023), arXiv:2307.05200 .
  22. A. Anshu, Concentration bounds for quantum states with finite correlation length on quantum spin lattice systems,  18, 083011 (2016).
  23. C. Rouzé, D. S. França, and Á. M. Alhambra, Efficient thermalization and universal quantum computing with quantum Gibbs samplers (2024), arXiv:2403.12691 .
  24. A. Riera, C. Gogolin, and J. Eisert, Thermalization in nature and on a quantum computer, Phys. Rev. Lett. 108, 080402 (2012).
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