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二氮合铁配合物[(TPB)FeN]的电子结构:与穆斯堡尔参数的相关性

Electronic structure of iron dinitrogen complex [(TPB)FeN]: correlation to Mössbauer parameters.

作者信息

Vyas Nidhi, Kumar Aditya, Ojha Animesh K, Grover Abhinav

机构信息

School of Biotechnology, Jawaharlal Nehru University New Delhi-110067 India

Department of Physics, Motilal Nehru National Institute of Technology Allahabad-211004 India.

出版信息

RSC Adv. 2020 Feb 25;10(13):7948-7955. doi: 10.1039/c9ra10481j. eCollection 2020 Feb 18.

DOI:10.1039/c9ra10481j
PMID:35492201
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9049905/
Abstract

Low-valent species of iron are key intermediates in many important biological processes such as the nitrogenase enzymatic catalytic reaction. These species play a major role in activating highly stable N molecules. Thus, there is a clear need to establish the factors which are responsible for the reactivity of the metal-dinitrogen moiety. In this regard, we have investigated the electronic structure of low-valent iron (2-/1-/0) in a [(TPB)FeN] complex using density functional theory (DFT). The variation in the oxidation states of iron in the nitrogenase enzyme cycle is associated with the flexibility of Fe→B bonding. Therefore, the flexibility of Fe→B bonding acts as an electron source that sustains the formation of various oxidation states, which is necessary for the key species in dinitrogen activation. AIM calculations are also performed to understand the strength of Fe→B and Fe-N bonds. A detailed interpretation of the contributions to the isomer shift (IS) and quadrupole splitting (Δ ) are discussed. The major contribution to IS comes mainly from the 3s-contribution, which differs depending on the d orbital population due to different shielding. The valence shell contribution also comes from the 4s-orbital. The Fe-N bond distance has a great influence on the Mössbauer parameters, which are associated with the radial distribution, the shape of the 4s-orbital and the charge density at the nucleus. A linear relationship between IS with Fe-N and Δ with Fe-N is observed.

摘要

低价铁物种是许多重要生物过程中的关键中间体,如固氮酶催化反应。这些物种在激活高度稳定的氮分子中起主要作用。因此,明确需要确定负责金属 - 二氮部分反应性的因素。在这方面,我们使用密度泛函理论(DFT)研究了[(TPB)FeN]配合物中低价铁(2 - /1 - /0)的电子结构。固氮酶循环中铁氧化态的变化与Fe→B键的灵活性有关。因此,Fe→B键的灵活性作为一种电子源,维持各种氧化态的形成,这对于二氮活化中的关键物种是必要的。还进行了AIM计算以了解Fe→B和Fe - N键的强度。讨论了对同质异能位移(IS)和四极分裂(Δ)贡献的详细解释。对IS的主要贡献主要来自3s贡献,由于不同屏蔽导致的d轨道占据情况不同,该贡献也不同。价层贡献也来自4s轨道。Fe - N键距离对穆斯堡尔参数有很大影响,这些参数与径向分布、4s轨道形状和原子核处的电荷密度有关。观察到IS与Fe - N以及Δ与Fe - N之间的线性关系。

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