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高效的水氧化催化剂催化循环研究工作流程:结合 GFN-xTB 和密度泛函理论。

Efficient workflow for the investigation of the catalytic cycle of water oxidation catalysts: Combining GFN-xTB and density functional theory.

机构信息

Leiden Institute of Chemistry, Leiden University, Leiden, The Netherlands.

Department of Chemistry and Pharmaceutical Sciences, Vrije Universiteit Amsterdam, Amsterdam, The Netherlands.

出版信息

J Comput Chem. 2021 Oct 5;42(26):1885-1894. doi: 10.1002/jcc.26721. Epub 2021 Jul 18.

DOI:10.1002/jcc.26721
PMID:34278594
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8456855/
Abstract

Photocatalytic water oxidation remains the bottleneck in many artificial photosynthesis devices. The efficiency of this challenging process is inherently linked to the thermodynamic and electronic properties of the chromophore and the water oxidation catalyst (WOC). Computational investigations can facilitate the search for favorable chromophore-catalyst combinations. However, this remains a demanding task due to the requirements on the computational method that should be able to correctly describe different spin and oxidation states of the transition metal, the influence of solvation and the different rates of the charge transfer and water oxidation processes. To determine a suitable method with favorable cost/accuracy ratios, the full catalytic cycle of a molecular ruthenium based WOC is investigated using different computational methods, including density functional theory (DFT) with different functionals (GGA, Hybrid, Double Hybrid) as well as the semi-empirical tight binding approach GFN-xTB. A workflow with low computational cost is proposed that combines GFN-xTB and DFT and provides reliable results. GFN-xTB geometries and frequencies combined with single-point DFT energies give free energy changes along the catalytic cycle that closely follow the full DFT results and show satisfactory agreement with experiment, while significantly decreasing the computational cost. This workflow allows for cost efficient determination of energetic, thermodynamic and dynamic properties of WOCs.

摘要

光催化水氧化仍然是许多人工光合作用器件中的瓶颈。这个具有挑战性的过程的效率本质上与发色团和水氧化催化剂 (WOC) 的热力学和电子性质有关。计算研究可以促进有利的发色团-催化剂组合的搜索。然而,由于对计算方法的要求,这仍然是一项艰巨的任务,该方法应该能够正确描述过渡金属的不同自旋和氧化态、溶剂化的影响以及电荷转移和水氧化过程的不同速率。为了确定具有有利成本/精度比的合适方法,使用不同的计算方法研究了基于分子钌的 WOC 的完整催化循环,包括具有不同泛函(广义梯度近似 (GGA)、杂化、双杂化)的密度泛函理论 (DFT) 以及半经验紧束缚方法 GFN-xTB。提出了一种具有低计算成本的工作流程,该流程结合了 GFN-xTB 和 DFT,并提供了可靠的结果。GFN-xTB 几何形状和频率与单点 DFT 能量相结合,给出了催化循环中自由能变化,这些变化与全 DFT 结果密切相关,并与实验结果吻合良好,同时大大降低了计算成本。该工作流程允许对 WOC 的能量、热力学和动力学性质进行经济高效的确定。

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