Quantum Circuits Reproduce Experimental Two-dimensional Many-body
Localization Transition Point
- URL: http://arxiv.org/abs/2108.08268v3
- Date: Wed, 14 Feb 2024 08:15:26 GMT
- Title: Quantum Circuits Reproduce Experimental Two-dimensional Many-body
Localization Transition Point
- Authors: Joey Li, Amos Chan, Thorsten B. Wahl
- Abstract summary: We use fermionic quantum circuits as a variational method to approximate the full set of eigenstates of two-dimensional MBL systems.
We calculate the filling fraction-dependent MBL phase diagram, an important feature which has not been addressed in previous literature.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: While many studies point towards the existence of many-body localization
(MBL) in one dimension, the fate of higher-dimensional strongly disordered
systems is a topic of current debate. The latest experiments as well as several
recent numerical studies indicate that such systems behave many-body localized
-- at least on practically relevant time scales. However, thus far, theoretical
approaches have been unable to quantitatively reproduce experimentally measured
MBL features -- an important requirement to demonstrate their validity. In this
work, we use fermionic quantum circuits as a variational method to approximate
the full set of eigenstates of two-dimensional MBL systems realized in
fermionic optical lattice experiments. Using entanglement-based features, we
obtain a phase transition point in excellent agreement with the experimentally
measured value. Moreover, we calculate, the filling fraction-dependent MBL
phase diagram, an important feature which has not been addressed in previous
literature. We argue that our approach best captures the underlying
charge-density-wave experiments and compute the mean localization lengths,
which can be compared to future experiments.
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