A self-adaptive first-principles approach for magnetic excited states

Zefeng Cai, Ke Wang, Yong Xu, Su-Huai Wei, Ben Xu
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Abstract

The profound impact of excited magnetic states on the intricate interplay between electron and lattice behaviors in magnetic materials is a topic of great interest. Unfortunately, despite the significant strides that have been made in first-principles methods, accurately tracking these phenomena remains a challenging and elusive task. The crux of the challenge that lies before us is centered on the intricate task of characterizing the magnetic configuration of an excited state, utilizing a first-principle approach that is firmly rooted in the ground state of the system. We propose a versatile self-adaptive spin-constrained density functional theory formalism. By iteratively optimizing the constraining field alongside the electron wave function during energy minimization, we are able to obtain an accurate potential energy surface that captures the longitudinal and transverse variations of magnetization in itinerant ferromagnetic Fe. Moreover, this technique allows us to identify the subtle coupling between magnetic moments and other degrees of freedom by tracking energy variation, providing new insights into the intricate interplay between magnetic interactions, electronic band structure, and phonon dispersion curves in single-layered \(\mathrm{CrI} _{3}\). This new methodology represents a significant breakthrough in our ability to probe the complex and multifaceted properties of magnetic systems.

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磁激发态的自适应第一性原理方法
激发态对磁性材料中电子和晶格行为之间复杂相互作用的深刻影响是一个非常有趣的话题。不幸的是,尽管第一原理方法取得了重大进展,但准确追踪这些现象仍然是一项具有挑战性和难以捉摸的任务。摆在我们面前的挑战的关键是集中在描述激发态的磁结构的复杂任务上,利用牢固地植根于系统基态的第一原理方法。提出了一种通用的自适应自旋约束密度泛函理论形式。通过在能量最小化过程中与电子波函数一起迭代优化约束场,我们能够获得一个精确的势能面,该势能面可以捕捉到流动铁磁铁中磁化强度的纵向和横向变化。此外,该技术允许我们通过跟踪能量变化来识别磁矩和其他自由度之间的微妙耦合,为单层中磁相互作用,电子能带结构和声子色散曲线之间的复杂相互作用提供了新的见解\(\mathrm{CrI} _{3}\)。这种新方法代表了我们探测磁系统复杂和多方面特性的能力的重大突破。
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