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通过量子计算揭示内嵌富勒烯H O@C中对称性破缺的起源

Unraveling the Origin of Symmetry Breaking in H O@C Endofullerene Through Quantum Computations.

作者信息

Carrillo-Bohórquez Orlando, Valdés Álvaro, Prosmiti Rita

机构信息

Institute of Fundamental Physics (IFF-CSIC), CSIC, Serrano 123, 28006, Madrid, Spain.

Departamento de Física, Universidad Nacional de Colombia, Calle 26, Cra 39, Edificio 404, Bogotá, Colombia.

出版信息

Chemphyschem. 2022 May 4;23(9):e202200034. doi: 10.1002/cphc.202200034. Epub 2022 Mar 14.

Abstract

We explore the origin of the anomalous splitting of the 1 levels reported experimentally for the H O@C endofullerene, in order to give some insight about the physical interpretations of the symmetry breaking observed. We performed fully-coupled quantum computations within the multiconfiguration time-dependent Hartree approach employing a rigorous procedure to handle such computationally challenging problems. We introduce two competing physical models, and discuss the observed unconventional quantum patterns in terms of anisotropy in the interfullerene interactions, caused by the change in the off-center position of the encapsulated water molecules inside the cage or the uniaxial C -cage distortion, arising from noncovalent bonding upon water's encapsulation, or exohedral fullerene perturbations. Our results show that both scenarios could reproduce the experimentally observed rotational degeneracy pattern, although quantitative agreement with the available experimental rotational levels splitting value has been achieved by the model that considers an uniaxial elongation of the C -cage. Such finding supports that the observed symmetry breaking could be mainly caused by the distortion of the fullerene cage. However, as nuclear quantum treatments rely on the underlying interactions, a decisive conclusion hinges on the availability of their improved description, taken into account both endofullerene and exohedral environments, from forthcoming highly demanding electronic structure many-body interaction studies.

摘要

我们探究了实验报道的H₂O@C内嵌富勒烯中1能级异常分裂的起源,以便对所观察到的对称性破缺的物理解释有所深入了解。我们在多组态含时 Hartree 方法内进行了全耦合量子计算,采用了严格的程序来处理此类计算上具有挑战性的问题。我们引入了两种相互竞争的物理模型,并根据笼内封装水分子偏心位置的变化或由于水分子封装时的非共价键合或外表面富勒烯微扰引起的笼状C₆₀单轴畸变所导致的富勒烯间相互作用的各向异性,来讨论所观察到的非常规量子模式。我们的结果表明,尽管考虑笼状C₆₀单轴伸长的模型已实现了与现有实验转动能级分裂值的定量一致,但这两种情况都能重现实验观察到的转动简并模式。这一发现支持所观察到的对称性破缺可能主要由富勒烯笼的畸变引起。然而,由于核量子处理依赖于潜在的相互作用,一个决定性的结论取决于即将开展的对电子结构多体相互作用要求极高的研究中,对内嵌富勒烯和外表面环境进行改进描述的可行性。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/f8c7/9311847/a95be6a897ea/CPHC-23-0-g005.jpg

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