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arxiv: 2311.17920 · v1 · pith:5E6RAEQ7 · submitted 2023-11-29 · cond-mat.str-el · cond-mat.dis-nn· physics.comp-ph

Autoencoder-based analytic continuation method for strongly correlated quantum systems

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classification cond-mat.str-el cond-mat.dis-nnphysics.comp-ph
keywords analyticcontinuationfunctionmethodproblemspectralapproachcorrelated
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The single particle Green's function provides valuable information on the momentum and energy-resolved spectral properties for a strongly correlated system. In large-scale numerical calculations using quantum Monte Carlo (QMC), dynamical mean field theory (DMFT), including cluster-DMFT, one usually obtains the Green's function in imaginary-time $G(\tau)$. The process of inverting a Laplace transform to obtain the spectral function $A(\omega)$ in real-frequency is an ill-posed problem and forms the core of the analytic continuation problem. In this Letter, we propose to use a completely unsupervised autoencoder-type neural network to solve the analytic continuation problem. We introduce an encoder-decoder approach that, together with only minor physical assumptions, can extract a high-quality frequency response from the imaginary time domain. With a deeply tunable architecture, this method can, in principle, locate sharp features of spectral functions that might normally be lost using already well-established methods, such as maximum entropy (MaxEnt) methods. We demonstrate the strength of the autoencoder approach by applying it to QMC results of $G(\tau)$ for a single-band Hubbard model. The proposed method is general and can also be applied to other ill-posed inverse problems.

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