Steady-state properties of multi-orbital systems using quantum Monte Carlo

Erpenbeck, A.; Blommel, T.; Zhang, L.; Lin, W.-T.; Cohen, G.; Gull, E.

doi:10.1063/5.0226253

The Journal of Chemical Physics

2024

DOI: 10.1063/5.0226253

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Steady-state properties of multi-orbital systems using quantum Monte Carlo

A. Erpenbeck,

T. Blommel,

L. Zhang

et al.

Abstract: A precise dynamical characterization of quantum impurity models with multiple interacting orbitals is challenging. In quantum Monte Carlo methods, this is embodied by sign problems. A dynamical sign problem makes it exponentially difficult to simulate long times. A multi-orbital sign problem generally results in a prohibitive computational cost for systems with multiple impurity degrees of freedom even in static equilibrium calculations. Here, we present a numerically exact inchworm method that simultaneously … Show more

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2024

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Cited by 2 publications

References 106 publications

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Nonequilibrium steady state full counting statistics in the noncrossing approximation

Zemach,

Erpenbeck,

Gull

et al. 2024

The Journal of Chemical Physics

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Quantum transport is often characterized not just by mean observables like the particle or energy current but by their fluctuations and higher moments, which can act as detailed probes of the physical mechanisms at play. However, relatively few theoretical methods are able to access the full counting statistics (FCS) of transport processes through electronic junctions in strongly correlated regimes. While most experiments are concerned with steady state properties, most accurate theoretical methods rely on computationally expensive propagation from a tractable initial state. Here, we propose a simple approach for computing the FCS through a junction directly at the steady state, utilizing the propagator noncrossing approximation. Compared to time propagation, our method offers reduced computational cost at the same level of approximation, but the idea can also be used within other approximations or as a basis for numerically exact techniques. We demonstrate the method’s capabilities by investigating the impact of lead dimensionality on electronic transport in the nonequilibrium Anderson impurity model at the onset of Kondo physics. Our results reveal a distinct signature of one dimensional leads in the noise and Fano factor not present for other dimensionalities, showing the potential of FCS measurements as a probe of the environment surrounding a quantum dot.

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Nonequilibrium steady state full counting statistics in the noncrossing approximation

Zemach,

Erpenbeck,

Gull

et al. 2024

The Journal of Chemical Physics

View full text Add to dashboard Cite

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Unveiling hidden scaling relations in dissipative relaxation dynamics of strongly correlated quantum impurity systems

Ding,

Zhang,

Zhang

et al. 2024

The Journal of Chemical Physics

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Understanding the time evolution of strongly correlated open quantum systems (OQSs) in response to perturbations (quenches) is of fundamental importance to the precise control of quantum devices. It is, however, rather challenging in multi-impurity quantum systems because such evolution often involves multiple intricate dynamical processes. In this work, we apply the numerically exact hierarchical equations of motion approach to explore the influence of two different types of perturbations, i.e., sudden swapping of the energy levels of impurity systems and activating the inter-impurity spin-exchange interaction, on the dissipation dynamics of the Kondo-correlated two-impurity Anderson model over a wide range of energetic parameters. By evaluating the time-dependent impurity spectral function and other system properties, we analyze the time evolution of the Kondo state in detail and conclude a phenomenologically scaling relation for Kondo dynamics driven by these perturbations. The evolutionary scaling relationship is not only related to the Kondo characteristic energy TK but also significantly affected by the simultaneous non-Kondo dynamic characteristic energy. We expect these results will inspire subsequent theoretical studies on the dynamics of strongly correlated OQSs.

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Steady-state properties of multi-orbital systems using quantum Monte Carlo

Cited by 2 publications

References 106 publications

Nonequilibrium steady state full counting statistics in the noncrossing approximation

Nonequilibrium steady state full counting statistics in the noncrossing approximation

Unveiling hidden scaling relations in dissipative relaxation dynamics of strongly correlated quantum impurity systems

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