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Published July 29, 2024 | Published
Journal Article Open

Efficient simulation of low-temperature physics in one-dimensional gapless systems

Kusuki, Yuya1, 2 ORCID icon
Tamaoka, Kotaro3 ORCID icon
Wei, Zixia4, 2, 5 ORCID icon
Yoneta, Yasushi2, 6 ORCID icon
  • 1. ROR icon California Institute of Technology
  • 2. ROR icon RIKEN
  • 3. ROR icon Nihon University
  • 4. ROR icon Harvard University
  • 5. ROR icon Kyoto University
  • 6. ROR icon University of Tokyo

Abstract

We discuss the computational efficiency of the finite-temperature simulation with minimally entangled typical thermal states (METTS). To argue that METTS can be efficiently represented as matrix product states, we present an analytic upper bound for the average entanglement Rényi entropy of METTS for a Rényi index 0<𝑞≤1. In particular, for one-dimensional (1D) gapless systems described by conformal field theories, the upper bound scales as 𝑂⁡(𝑐⁢𝑁0⁢log⁡𝛽) where 𝑐 is the central charge and 𝑁 is the system size. Furthermore, we numerically find that the average Rényi entropy exhibits a universal behavior characterized by the central charge and is roughly given by half of the analytic upper bound. Based on these results, we show that METTS can provide a speedup compared to employing the purification method to analyze thermal equilibrium states at low temperatures in 1D gapless systems.

Copyright and License

©2024 American Physical Society.

Acknowledgement

We are grateful to Tomotaka Kuwahara, Hiroyasu Tajima, Tadashi Takayanagi, and Yantao Wu for useful discussions. We would like to especially thank Yoshifumi Nakata and Yantao Wu for careful reading and valuable comments on a draft of this manuscript.

Funding

Y.K. is supported by the Brinson Prize Fellowship at Caltech and the U.S. Department of Energy, Office of Science, Office of High Energy Physics, under Award No. DE-SC0011632. K.T. is supported by Grant-in-Aid for Early-Career Scientists No. 21K13920 and Grant-in-Aid for Transformative Research Areas (A) No. 22H05265. Z.W. is supported by the Society of Fellows at Harvard University.

Supplemental Material

Supplemental material (PDF)

A detailed proof of the theorem 1 in the main text and additional numerical results are presented in the supplemental file.

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October 29, 2024
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November 8, 2024