Scaling of many-body localization transitions: Quantum dynamics in Fock space and real space

TL;DR

This paper investigates many-body localization transitions across different models by analyzing quantum dynamics in Fock and real space, revealing how transition points scale with system size and providing insights for experimental quantum simulations.

Contribution

It introduces a unified approach to study MBL transitions using generalized imbalance and fluctuation analysis across various models, highlighting the scaling behavior of transition points with system size.

Findings

Transition points grow as a power law in QREM and QD models.

In 1D models, transition points are independent of system size.

Feasibility of experimental studies on large systems with quantum simulators.

Abstract

Many-body-localization (MBL) transitions are studied in a family of single-spin-flip spin-$\frac12$ models, including the one-dimensional (1D) chain with nearest-neighbor interactions, the quantum dot (QD) model with all-to-all pair interactions, and the quantum random energy model (QREM). We investigate the generalized imbalance that characterizes propagation in Fock space out of an initial basis state and, at the same time, can be efficiently probed by real-space measurements. For all models considered, the average imbalance and its quantum and mesoscopic fluctuations provide excellent indicators for the position of the MBL transition $W_c(n)$, where $n$ is the number of spins. Combining these findings with earlier results on level statistics, we determine phase diagrams of the MBL transitions in the $n$-$W$ plane. Our results provide evidence for a direct transition between the ergodic and MBL phases for each of the models, without any intermediate phase. For QREM and QD model, $W_c(n)$ grows as a power law of $n$ (with logarithmic corrections), in agreement with analytical predictions $W_c^{\rm QREM}(n) \sim n^{1/2} \ln n$ and $W_c^{\rm QD}(n) \gtrsim n^{3/4} \ln^{1/2} n$. This growth is in stark contrast to the 1D model, where $W_c(n)$ is essentially independent of $n$, consistent with the analytic expectation $W_c^{\rm 1D}(n\to \infty)= {\rm const}$. We also determine the scaling of the transition width $\Delta W (n) / W_c(n)$ and estimate the system size $n$ needed to study the asymptotic scaling behavior. While these values of $n$ are not accessible to exact simulations on a classical computer, they are within the reach of quantum simulators. Our results indicate feasibility of experimental studies of $n$-$W$ phase diagrams and scaling properties of MBL transitions in models of 1D and QD type and in their extensions to other spatial geometry or distance-dependent interactions.