Quantum embedding for molecules using auxiliary particles – the ghost Gutzwiller Ansatz

IF 3.4 3区 化学 Q2 Chemistry Faraday Discussions Pub Date : 2024-04-16 DOI:10.1039/D4FD00053F
Carlos Mejuto-Zaera
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Abstract

Strong/static electronic correlation mediates the emergence of remarkable phases of matter, and underlies the exceptional reactivity properties in transition metal-based catalysts. Modeling strongly correlated molecules and solids calls for multi-reference Ansätze, which explicitly capture the competition of energy scales characteristic of such systems. With the efficient computational screening of correlated solids in mind, the ghost Gutzwiller (gGut) Ansatz has been recently developed. This is a variational Ansatz which can be formulated as a self-consistent embedding approach, describing the system within a non-interacting, quasiparticle model, yet providing accurate spectra in both low and high energy regimes. Crucially, small fragments of the system are identified as responsible for the strong correlation, and are therefore enhanced by adding a set of auxiliary orbitals, the ghosts. These capture many-body correlations through one-body fluctuations and subsequent out-projection when computing physical observables. gGut has been shown to accurately describe multi-orbital lattice models at modest computational cost. In this work, we extend the gGut framework to strongly correlated molecules, for which it holds special promise. Indeed, despite the asymmetric embedding treatment, the quasiparticle Hamiltonian effectively describes all major sources of correlation in the molecule: strong correlation through the ghosts in the fragment, and dynamical correlation through the quasiparticle description of its environment. To adapt the gGut Ansatz for molecules, we address the fact that, unlike in the lattice model previously considered, electronic interactions in molecules are not local. Hence, we explore a hierarchy of approximations of increasing accuracy capturing interactions between fragments and environment, and within the environment, and discuss how these affect the embedding description of correlations in the whole molecule. We will compare the accuracy of the gGut model with established methods to capture strong correlation within active space formulations, and assess the realistic use of this novel approximation to the theoretical description of correlated molecular clusters.

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带有辅助粒子的分子的量子嵌入--幽灵古茨维勒公式
强/静态电子相关性介导了非凡物质相的出现,也是过渡金属催化剂特殊反应特性的基础。强相关分子和固体的建模需要多参考解析,以明确捕捉此类系统特有的能级竞争。考虑到相关固体的高效计算筛选,最近开发出了幽灵古茨维勒(gGut)反演算法。这是一种变分公式,可表述为自洽嵌入方法,在非相互作用的准粒子模型中描述系统,同时提供低能和高能状态下的精确光谱。最重要的是,该系统的小碎片被确定为造成强相关性的原因,因此通过添加一组辅助轨道--"幽灵"--来增强其相关性。gGut 已被证明能以适度的计算成本精确描述多轨道晶格模型。在这项工作中,我们将 gGut 框架扩展到强相关分子,因为它在这方面具有特殊的前景。事实上,尽管采用了非对称嵌入处理,但准粒子哈密顿有效地描述了分子中所有主要的相关性来源:通过片段中的幽灵实现的强相关性,以及通过对其环境的准粒子描述实现的动态相关性。与之前考虑的晶格模型不同,分子中的电子相互作用不是局部的。因此,我们探索了一个精度不断提高的近似层次,以捕捉片段与环境之间以及环境内部的相互作用,并讨论这些近似如何影响整个分子中相关性的嵌入描述。我们将比较 gGut 模型与现有方法的准确性,以捕捉活性空间公式中的强相关性,并评估这种新近似方法在相关分子团簇理论描述中的实际应用。
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来源期刊
Faraday Discussions
Faraday Discussions CHEMISTRY, PHYSICAL-
CiteScore
4.90
自引率
0.00%
发文量
259
审稿时长
2.8 months
期刊介绍: Discussion summary and research papers from discussion meetings that focus on rapidly developing areas of physical chemistry and its interfaces
期刊最新文献
Back cover List of participants Poster list Correction: Challenges with relativistic GW calculations in solids and molecules List of participants
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