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高价过渡金属氧代(M=O)和过氧代(MOO)化合物的化学键本质:从经典计算到量子计算对金属氧自由基特性的历史视角

The Nature of the Chemical Bonds of High-Valent Transition-Metal Oxo (M=O) and Peroxo (MOO) Compounds: A Historical Perspective of the Metal Oxyl-Radical Character by the Classical to Quantum Computations.

作者信息

Yamaguchi Kizashi, Isobe Hiroshi, Shoji Mitsuo, Kawakami Takashi, Miyagawa Koichi

机构信息

SANKEN, Osaka University, Ibaraki 567-0047, Osaka, Japan.

Center for Quantum Information and Quantum Biology (QIQB), Osaka University, Toyonaka 560-0043, Osaka, Japan.

出版信息

Molecules. 2023 Oct 16;28(20):7119. doi: 10.3390/molecules28207119.

DOI:10.3390/molecules28207119
PMID:37894598
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10609222/
Abstract

This review article describes a historical perspective of elucidation of the nature of the chemical bonds of the high-valent transition metal oxo (M=O) and peroxo (M-O-O) compounds in chemistry and biology. The basic concepts and theoretical backgrounds of the broken-symmetry (BS) method are revisited to explain orbital symmetry conservation and orbital symmetry breaking for the theoretical characterization of four different mechanisms of chemical reactions. Beyond BS methods using the natural orbitals (UNO) of the BS solutions, such as UNO CI (CC), are also revisited for the elucidation of the scope and applicability of the BS methods. Several chemical indices have been derived as the conceptual bridges between the BS and beyond BS methods. The BS molecular orbital models have been employed to explain the metal oxyl-radical character of the M=O and M-O-O bonds, which respond to their radical reactivity. The isolobal and isospin analogy between carbonyl oxide RC-O-O and metal peroxide LFe-O-O has been applied to understand and explain the chameleonic chemical reactivity of these compounds. The isolobal and isospin analogy among Fe=O, O=O, and O have also provided the triplet atomic oxygen (O) model for non-heme Fe(IV)=O species with strong radical reactivity. The chameleonic reactivity of the compounds I (Cpd I) and II (Cpd II) is also explained by this analogy. The early proposals obtained by these theoretical models have been examined based on recent computational results by hybrid DFT (UHDFT), DLPNO CCSD(T), CASPT2, and UNO CI (CC) methods and quantum computing (QC).

摘要

这篇综述文章描述了在化学和生物学中阐明高价过渡金属氧代(M=O)和过氧代(M-O-O)化合物化学键性质的历史视角。重新审视了破缺对称性(BS)方法的基本概念和理论背景,以解释化学反应四种不同机制理论表征中的轨道对称性守恒和轨道对称性破缺。除了使用BS解的自然轨道(UNO)的BS方法,如UNO CI(CC),也重新审视了它们以阐明BS方法的范围和适用性。已经推导出了几个化学指标作为BS方法和超越BS方法之间的概念桥梁。BS分子轨道模型已被用于解释M=O和M-O-O键的金属氧自由基特性,这与其自由基反应性相关。羰基氧化物RC-O-O和金属过氧化物LFe-O-O之间的等瓣和等自旋类比已被用于理解和解释这些化合物的变色龙化学反应性。Fe=O、O=O和O之间的等瓣和等自旋类比也为具有强自由基反应性的非血红素Fe(IV)=O物种提供了三重态原子氧(O)模型。化合物I(Cpd I)和II(Cpd II)的变色龙反应性也用这种类比来解释。基于最近通过混合密度泛函理论(UHDFT)、DLPNO CCSD(T)、CASPT2和UNO CI(CC)方法以及量子计算(QC)得到的计算结果,对这些理论模型早期提出的观点进行了检验。

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