\begin{document}$ \hat{H}=\displaystyle\sum\limits_{j}^{L-1}\left[ -J\left( \hat{b}_{j}^{\dagger}\hat{b}_{j+1}+\hat {b}_{j+1}^{\dagger}\hat{b}_{j}\right) +\frac{1}{2}\left( U-{\mathrm{i}}\gamma_{j}\right) \hat{n}_{j}\hat{n}_{j+1}\right] \notag,$\end{document} with the random two-body loss \begin{document}$\gamma_j\in\left[0,W\right]$\end{document}. By the level statistics, the system undergoes a transition from the AI\begin{document}$^{\dagger}$\end{document} symmetry class to a two-dimensional Poisson ensemble with the increase of disorder strength. This transition is accompanied by the changing of the average magnitude (argument) \begin{document}$\overline{\left\langle {r}\right\rangle}$\end{document} (\begin{document}$\overline{-\left\langle \cos {\theta}\right\rangle }$\end{document}) of the complex spacing ratio, shifting from approximately 0.722 (0.193) to about 2/3 (0). The normalized participation ratios of the majority of eigenstates exhibit finite values in the ergodic phase, gradually approaching zero in the non-Hermitian MBL phase, which quantifies the degree of localization for the eigenstates. For weak disorder, one can see that average half-chain entanglement entropy \begin{document}$\overline{\langle S \rangle}$\end{document} follows a volume law in the ergodic phase. However, it decreases to a constant independent of L in the deep non-Hermitian MBL phase, adhering to an area law. These results indicate that the ergodic phase and non-Hermitian MBL phase can be distinguished by the half-chain entanglement entropy, even in non-Hermitian system, which is similar to the scenario in Hermitian system. Finally, for a short time, the dynamic evolution of the entanglement entropy exhibits linear growth with the weak disorder. In strong disorder case, the short-time evolution of \begin{document}$\overline{S(t)}$\end{document} shows logarithmic growth. However, when \begin{document}$t\geqslant10^2$\end{document}, \begin{document}$\overline{S(t)}$\end{document} can stabilize and tend to the steady-state half-chain entanglement entropy \begin{document}$\overline{ S_0 }$\end{document}. The results of the dynamical evolution of \begin{document}$\overline{S(t)}$\end{document} imply that one can detect the occurrence of the non-Hermitian MBL by the short-time evolution of \begin{document}$\overline{S(t)}$\end{document}, and the long-time behavior of \begin{document}$\overline{S(t)}$\end{document} signifies the steady-state information."> - 必威体育下载

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Liu Jing-Hu, Xu Zhi-Hao
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  • Abstract views:1404
  • PDF Downloads:84
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Publishing process
  • Received Date:19 December 2023
  • Accepted Date:11 January 2024
  • Available Online:18 January 2024
  • Published Online:05 April 2024

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