Many-body localization in XY spin chains with long-range interactions: An exact diagonalization study
Abstract
We investigate the transition from the many-body localized phase to the ergodic thermalized phase at an infinite temperature in an spin chain with spins, which experiences power-law decaying interactions in the form of () and a random transverse field. By performing large-scale exact diagonalization for the chain size up to , we systematically analyze the energy gap statistics, half-chain entanglement entropy, and uncertainty of the entanglement entropy of the system at different interaction exponents . The finite-size critical scaling allows us to determine the critical disorder strength and critical exponent at the many-body localization phase transition, as a function of the interaction exponent in the limit . We find that both and diverge when decreases to a critical power , indicating the absence of many-body localization for . Our result is useful to resolve the contradiction on the critical power found in two previous studies, from scaling argument in Phys. Rev. B \textbf{92}, 104428 (2015) and from quantum dynamics simulation in Phys. Rev. A \textbf{99}, 033610 (2019).
Cite
@article{arxiv.1908.04031,
title = {Many-body localization in XY spin chains with long-range interactions: An exact diagonalization study},
author = {Sebastian Schiffer and Jia Wang and Xia-Ji Liu and Hui Hu},
journal= {arXiv preprint arXiv:1908.04031},
year = {2019}
}
Comments
9 pages, 9 figures