利用威尔金森催化剂模型对乙烯加氢反应路径网络进行化学分析。

IF 2.8 4区 医学 Q3 CHEMISTRY, MEDICINAL Molecular Informatics Pub Date : 2024-08-09 DOI:10.1002/minf.202400063
Philippe Gantzer, Ruben Staub, Yu Harabuchi, Satoshi Maeda, Alexandre Varnek
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引用次数: 0

摘要

如果采用传统的基于图形的方法,大型化学反应网络的可视化和分析就会变得相当具有挑战性。作为替代方案,我们建议使用化学制图("chemography")方法,在二维地图上描述数据分布。在这里,生成地形图(GTM)算法--一种先进的化学制图方法--被应用于简化的威尔金森催化剂催化氢化反应路径网络的可视化,该网络包含在人工力诱导反应(AFIR)方法的帮助下,利用密度泛函理论或神经网络势能(NNP)进行势能面计算而生成的约 105 个结构。通过使用新的原子排列不变三维描述符进行结构编码,我们证明了 GTM 具有对具有相同二维表示的结构进行聚类、可视化势能面、提供反应路径探索随时间变化的洞察力以及比较使用不同能量评估方法获得的反应路径网络的能力。
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Chemography-guided analysis of a reaction path network for ethylene hydrogenation with a model Wilkinson's catalyst.

Visualization and analysis of large chemical reaction networks become rather challenging when conventional graph-based approaches are used. As an alternative, we propose to use the chemical cartography ("chemography") approach, describing the data distribution on a 2-dimensional map. Here, the Generative Topographic Mapping (GTM) algorithm - an advanced chemography approach - has been applied to visualize the reaction path network of a simplified Wilkinson's catalyst-catalyzed hydrogenation containing some 105 structures generated with the help of the Artificial Force Induced Reaction (AFIR) method using either Density Functional Theory or Neural Network Potential (NNP) for potential energy surface calculations. Using new atoms permutation invariant 3D descriptors for structure encoding, we've demonstrated that GTM possesses the abilities to cluster structures that share the same 2D representation, to visualize potential energy surface, to provide an insight on the reaction path exploration as a function of time and to compare reaction path networks obtained with different methods of energy assessment.

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来源期刊
Molecular Informatics
Molecular Informatics CHEMISTRY, MEDICINAL-MATHEMATICAL & COMPUTATIONAL BIOLOGY
CiteScore
7.30
自引率
2.80%
发文量
70
审稿时长
3 months
期刊介绍: Molecular Informatics is a peer-reviewed, international forum for publication of high-quality, interdisciplinary research on all molecular aspects of bio/cheminformatics and computer-assisted molecular design. Molecular Informatics succeeded QSAR & Combinatorial Science in 2010. Molecular Informatics presents methodological innovations that will lead to a deeper understanding of ligand-receptor interactions, macromolecular complexes, molecular networks, design concepts and processes that demonstrate how ideas and design concepts lead to molecules with a desired structure or function, preferably including experimental validation. The journal''s scope includes but is not limited to the fields of drug discovery and chemical biology, protein and nucleic acid engineering and design, the design of nanomolecular structures, strategies for modeling of macromolecular assemblies, molecular networks and systems, pharmaco- and chemogenomics, computer-assisted screening strategies, as well as novel technologies for the de novo design of biologically active molecules. As a unique feature Molecular Informatics publishes so-called "Methods Corner" review-type articles which feature important technological concepts and advances within the scope of the journal.
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