Accelerating Nonequilibrium Green Functions Simulations: The G1–G2 Scheme and Beyond

IF 1.5 4区物理与天体物理 Q3 PHYSICS, CONDENSED MATTER

Physica Status Solidi B-basic Solid State Physics Pub Date : 2024-04-26 DOI:10.1002/pssb.202300578

Michael Bonitz, Jan‐Philip Joost, Christopher Makait, Erik Schroedter, Tim Kalsberger, Karsten Balzer

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Abstract

The theory of nonequilibrium Green functions (NEGF) has seen a rapid development over the recent three decades. Applications include diverse correlated many‐body systems in and out of equilibrium. Very good agreement with experiments and available exact theoretical results could be demonstrated if the proper selfenergy approximations were used. However, full two‐time NEGF simulations are computationally costly, as they suffer from a cubic scaling of the computation time with the simulation duration. Recently the G1–G2 scheme that exactly reformulates the generalized Kadanoff–Baym ansatz with Hartree–Fock propagators (HF‐GKBA) into time‐local equations is introduced, which achieves time‐linear scaling and allows for a dramatic speedup and extension of the simulations (Schluenzen et al. Phys. Rev. Lett. 2020, 124, 076601). Remarkably, this scaling is achieved quickly, and also for high‐level selfenergies, including the nonequilibrium GW and T‐matrix approximations (Joost et al. Phys. Rev. B 2020, 101, 245101). Even the dynamically screened ladder approximation is now feasible (Joost et al. Phys. Rev. B 2022, 105, 165155), and also applications to electron‐boson systems are demonstrated. Herein, an overview on recent results that are achieved with the G1–G2 scheme is presented. Problems and open questions are discussed and further ideas of how to overcome the current limitations of the scheme and present are presented. The G1–G2 scheme is illustrated by presenting applying it to the excitation dynamics of Hubbard clusters, to optical excitation of graphene, and to charge transfer during stopping of ions by correlated materials.

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加速非平衡格林函数模拟：G1-G2 方案及其他

近三十年来，非平衡格林函数（NEGF）理论得到了快速发展。其应用包括平衡和非平衡状态下的各种相关多体系统。如果使用适当的自能近似值，可以证明与实验和现有精确理论结果非常吻合。然而，全双时 NEGF 模拟的计算成本很高，因为它们的计算时间与模拟持续时间成立方比例关系。最近推出的 G1-G2 方案将广义卡达诺夫-贝姆方差与哈特里-福克传播者（HF-GKBA）精确地重新表述为时域方程，实现了时间-线性缩放，使模拟的速度和扩展性大大提高（Schluenzen 等人，Phys. Rev. Lett.）值得注意的是，这种缩放是快速实现的，也适用于高级自能，包括非平衡 GW 和 T 矩阵近似（Joost 等人，Phys. Rev. B 2020, 101, 245101）。即使是动态屏蔽梯形近似现在也是可行的（Joost 等人，Phys. Rev. B 2022, 105, 165155），而且在电子玻色子系统中的应用也得到了证明。在此，我们将概述使用 G1-G2 方案所取得的最新成果。讨论了存在的问题和未决问题，并就如何克服该方案目前的局限性提出了进一步的想法。通过将 G1-G2 方案应用于哈伯德团簇的激发动力学、石墨烯的光学激发以及相关材料阻止离子期间的电荷转移，对该方案进行了说明。

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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来源期刊

Physica Status Solidi B-basic Solid State Physics 物理-物理：凝聚态物理

CiteScore

3.30

自引率

6.20%

发文量

321

审稿时长

2 months

期刊介绍： physica status solidi is devoted to the thorough peer review and the rapid publication of new and important results in all fields of solid state and materials physics, from basic science to applications and devices. Being among the largest and most important international publications, the pss journals publish review articles, letters and original work as well as special issues and conference contributions. physica status solidi b – basic solid state physics is devoted to topics such as theoretical and experimental investigations of the atomistic and electronic structure of solids in general, phase transitions, electronic and optical properties of low-dimensional, nano-scale, strongly correlated, or disordered systems, superconductivity, magnetism, ferroelectricity etc.