Equilibrium Quantum Impurity Problems via Matrix Product State Encoding of the Retarded Action

• URL: http://arxiv.org/abs/2306.17216v1
• Date: Thu, 29 Jun 2023 18:00:01 GMT
• Title: Equilibrium Quantum Impurity Problems via Matrix Product State Encoding of the Retarded Action
• Authors: Benedikt Kloss, Julian Thoenniss, Michael Sonner, Alessio Lerose, Matthew T. Fishman, E. M. Stoudenmire, Olivier Parcollet, Antoine Georges, and Dmitry A. Abanin
• Abstract summary: In this Article, we explore the computational power of representing the retarded action as matrix product state (RAMPS) We demonstrate that the RAMPS approach reliably reaches the Kondo regime for a range of interaction strengths $U$, with a numerical error scaling as a weak power law with inverse temperature. Our results show that the RAMPS approach offers promise as an alternative tool for studying quantum impurity problems in regimes that challenge established methods.
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• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: In the $0+1$ dimensional imaginary-time path integral formulation of quantum impurity problems, the retarded action encodes the hybridization of the impurity with the bath. In this Article, we explore the computational power of representing the retarded action as matrix product state (RAMPS). We focus on the challenging Kondo regime of the single-impurity Anderson model, where non-perturbative strong-correlation effects arise at very low energy scales. We demonstrate that the RAMPS approach reliably reaches the Kondo regime for a range of interaction strengths $U$, with a numerical error scaling as a weak power law with inverse temperature. We investigate the convergence behavior of the method with respect to bond dimension and time discretization by analyzing the error of local observables in the full interacting problem and find polynomial scaling in both parameters. Our results show that the RAMPS approach offers promise as an alternative tool for studying quantum impurity problems in regimes that challenge established methods, such as multi-orbital systems. Overall, our study contributes to the development of efficient and accurate non-wavefunction-based tensor-network methods for quantum impurity problems.

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