Development of a fully coupled diabatic spin-orbit model for the photodissociation of phenyl iodide.

The Journal of chemical physics Pub Date : 2022-05-23 DOI:10.1063/5.0088205

Nicole Weike, Emma Chanut, Hannes Hoppe, W. Eisfeld

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Abstract

The theoretical treatment of the quantum dynamics of the phenyl iodide photodissociation requires an accurate analytical potential energy surface (PES) model. This model must also account for spin-orbit (SO) coupling. This study is the first step to construct accurate SO coupled PESs, namely, for the C-I dissociation coordinate. The model is based on the Effective Relativistic Coupling by Asymptotic Representation (ERCAR) method developed over the past ten years. The SO-free Hamiltonian is represented in an asymptotic diabatic basis and then combined with an atomic effective relativistic coupling operator determined analytically. In contrast to the previously studied cases (HI, CH3I), the diabatic basis states are due to excitations in the phenyl fragment rather than the iodine atom. An accurate analytical model of the ab initio reference data is determined in two steps. The first step is a simple reference model describing the data qualitatively. This reference model is corrected through a trained artificial neural-network to achieve high accuracy. The SO-free and the fine structure states resulting from this ERCAR model are discussed extensively in the context of the photodissociation.

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苯基碘化物光解完全耦合自旋轨道模型的建立。

对碘苯光解量子动力学的理论处理需要精确的分析势能面(PES)模型。这个模型还必须考虑自旋-轨道(SO)耦合。本研究是构建精确的SO耦合PESs(即C-I解离坐标)的第一步。该模型基于近十年来发展起来的有效相对论渐近表示耦合(ERCAR)方法。用渐近非绝热基表示无so的哈密顿量，然后与解析确定的原子有效相对论耦合算子结合。与先前研究的情况(HI, CH3I)相反，非绝热基态是由于苯基片段而不是碘原子的激发。通过两个步骤确定了从头算参考数据的精确解析模型。第一步是建立一个简单的参考模型，对数据进行定性描述。通过训练后的人工神经网络对参考模型进行校正，达到较高的精度。在光解的背景下，广泛讨论了由该ERCAR模型产生的无so和精细结构状态。

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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The Journal of chemical physics

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