Nevanlinna Analytic Continuation for Migdal-Eliashberg Theory

arXiv - PHYS - Computational Physics Pub Date : 2024-09-04 DOI:arxiv-2409.02737

D. M. Khodachenko, R. Lucrezi, P. N. Ferreira, M. Aichhorn, C. Heil

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Abstract

In this work, we present a method to reconstruct real-frequency properties from analytically continued causal Green's functions within the framework of Migdal-Eliashberg (ME) theory for superconductivity. ME theory involves solving a set of coupled equations self-consistently in imaginary frequency space, but to obtain experimentally measurable properties like the spectral function and quasiparticle density of states, it is necessary to perform an analytic continuation to real frequency space. Traditionally, the ME Green's function is decomposed into three fundamental complex functions, which are analytically continued independently. However, these functions do not possess the causal properties of Green's functions, complicating or even preventing the application of standard methods such as Maximum Entropy. Our approach overcomes these challenges, enabling the use of various analytic continuation techniques that were previously impractical. We demonstrate the effectiveness of this method by combining it with Nevanlinna analytic continuation to achieve accurate real-frequency results for ME theory, which are directly comparable to experimental data, with applications highlighted for the superconductors MgB$_2$ and LaBeH$_8$.

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米格达尔-埃利亚什伯格理论的内万林纳分析连续性

在这项工作中，我们提出了一种在米格达尔-埃利亚什伯格（Migdal-Eliashberg，ME）超导理论框架内，从解析续因果格林函数重建实频特性的方法。ME 理论涉及在虚频空间自洽地求解一组耦合方程，但要获得可实验测量的特性，如频谱函数和类粒子状态密度，就必须对实频空间进行解析续演。传统上，ME 格林函数被分解为三个基本复变函数，并对其进行独立的解析延续。然而，这些函数并不具备格林函数的因果特性，这使得最大熵等标准方法的应用变得复杂，甚至无法应用。我们的方法克服了这些难题，使以前不切实际的各种分析延续技术得以应用。我们证明了这种方法的有效性，将它与 Nevanlinna 分析延续相结合，为 ME 理论获得了精确的实频结果，这些结果可直接与实验数据进行比较，并重点介绍了在超导体 MgB$_2$ 和 LaBeH$_8$ 中的应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Computational Physics

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