Related papers: Tunable transport in the mass-imbalanced Fermi-Hubbard model

Tunable transport in the mass-imbalanced Fermi-Hubbard model

URL: http://arxiv.org/abs/2205.12970v2
Date: Mon, 29 Aug 2022 15:12:49 GMT
Title: Tunable transport in the mass-imbalanced Fermi-Hubbard model
Authors: Philip Zechmann, Alvise Bastianello, Michael Knap
Abstract summary: We study transport in the one-dimensional Hubbard model with different masses of the two fermionic species. For timescales accessible with matrix product operators, we find excellent agreement between these numerically exact results and the quantum Boltzmann equation. Our results demonstrate that the quantum Boltzmann equation is a useful tool to study complex non-equilibrium states in inhomogeneous potentials.
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License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The late-time dynamics of quantum many-body systems is organized in distinct dynamical universality classes, characterized by their conservation laws and thus by their emergent hydrodynamic transport. Here, we study transport in the one-dimensional Hubbard model with different masses of the two fermionic species. To this end, we develop a quantum Boltzmann approach valid in the limit of weak interactions. We explore the crossover from ballistic to diffusive transport, whose timescale strongly depends on the mass ratio of the two species. For timescales accessible with matrix product operators, we find excellent agreement between these numerically exact results and the quantum Boltzmann equation, even for intermediate interactions. We investigate two scenarios which have been recently studied with ultracold atom experiments. First, in the presence of a tilt, the quantum Boltzmann equation predicts that transport is significantly slowed down and becomes subdiffusive, consistent with previous studies. Second, we study transport probed by displacing a harmonic confinement potential and find good quantitative agreement with recent experimental data [N. Darkwah Oppong et al., arXiv:2011.12411]. Our results demonstrate that the quantum Boltzmann equation is a useful tool to study complex non-equilibrium states in inhomogeneous potentials, as often probed with synthetic quantum systems.