Numerical renormalization group calculations for magnetic impurity systems with spin-orbit coupling and crystal-field effects

arXiv - PHYS - Strongly Correlated Electrons Pub Date : 2024-09-18 DOI:arxiv-2409.12050

Aitor Calvo-Fernández, María Blanco-Rey, Asier Eiguren

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Abstract

Exploiting symmetries in the numerical renormalization group (NRG) method significantly enhances performance by improving accuracy, increasing computational speed, and optimizing memory efficiency. Published codes focus on continuous rotations and unitary groups, which generally are not applicable to systems with strong crystal-field effects. The PointGroupNRG code implements symmetries related to discrete rotation groups, which are defined by the user in terms of Clebsch-Gordan coefficients, together with particle conservation and spin rotation symmetries. In this paper we present a new version of the code that extends the available finite groups, previously limited to simply reducible point groups, in a way that all point and double groups become accessible. It also includes the full spin-orbital rotation group. Moreover, to improve the code's flexibility for impurities with complex interactions, this new version allows to choose between a standard Anderson Hamiltonian for the impurity or, as another novel feature, an ionic model that requires only the spectrum and the impurity Lehmann amplitudes.

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具有自旋轨道耦合和晶体场效应的磁性杂质系统的重正化群数值计算

利用数值重正化群（NRG）方法中的对称性，可以通过提高精度、增加计算速度和优化内存效率来显著增强性能。已发布的代码侧重于连续旋转和单元群，通常不适用于具有强晶场效应的系统。PointGroupNRG 代码实现了与离散旋转群相关的对称性，这些对称性由用户根据克莱布什-哥尔丹系数以及粒子守恒和自旋旋转对称性来定义。在本文中，我们介绍了该代码的一个新版本，它扩展了可用的有限群，以前仅限于简单可简化的点群，现在可以访问所有的点群和双群。它还包括完整的自旋轨道旋转群。此外，为了提高代码在处理具有复杂相互作用的杂质时的灵活性，新版本允许在杂质的标准安德森哈密顿或作为另一个新特性的离子模型之间进行选择，后者只需要频谱和杂质的莱曼振幅。

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 - Strongly Correlated Electrons

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