Related papers: Data Driven Reaction Mechanism Estimation via Transient Kinetics and Machine Learning

Data Driven Reaction Mechanism Estimation via Transient Kinetics and Machine Learning

URL: http://arxiv.org/abs/2011.08810v2
Date: Wed, 21 Apr 2021 14:26:49 GMT
Title: Data Driven Reaction Mechanism Estimation via Transient Kinetics and Machine Learning
Authors: M. Ross Kunz, Adam Yonge, Zongtang Fang, Andrew J. Medford, Denis Constales, Gregory Yablonsky, Rebecca Fushimi
Abstract summary: This work details a methodology based on the combination of transient rate/concentration dependencies and machine learning to measure the number of active sites. Experiment CO oxidation data was analyzed to reveal the Langmuir-Hinshelwood mechanism driving the reaction.
Score: 0.0
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Understanding the set of elementary steps and kinetics in each reaction is extremely valuable to make informed decisions about creating the next generation of catalytic materials. With physical and mechanistic complexity of industrial catalysts, it is critical to obtain kinetic information through experimental methods. As such, this work details a methodology based on the combination of transient rate/concentration dependencies and machine learning to measure the number of active sites, the individual rate constants, and gain insight into the mechanism under a complex set of elementary steps. This new methodology was applied to simulated transient responses to verify its ability to obtain correct estimates of the micro-kinetic coefficients. Furthermore, experimental CO oxidation data was analyzed to reveal the Langmuir-Hinshelwood mechanism driving the reaction. As oxygen accumulated on the catalyst, a transition in the mechanism was clearly defined in the machine learning analysis due to the large amount of kinetic information available from transient reaction techniques. This methodology is proposed as a new data driven approach to characterize how materials control complex reaction mechanisms relying exclusively on experimental data.

Related papers

ReactAIvate: A Deep Learning Approach to Predicting Reaction Mechanisms and Unmasking Reactivity Hotspots [4.362338454684645]
We develop an interpretable attention-based GNN that achieved near-unity and 96% accuracy for reaction step classification. Our model adeptly identifies key atom(s) even from out-of-distribution classes. This generalizabilty allows for the inclusion of new reaction types in a modular fashion, thus will be of value to experts for understanding the reactivity of new molecules.
arXiv Detail & Related papers (2024-07-14T05:53:18Z)
A Machine Learning and Explainable AI Framework Tailored for Unbalanced Experimental Catalyst Discovery [10.92613600218535]
We introduce a robust machine learning and explainable AI (XAI) framework to accurately classify the catalytic yield of various compositions. This framework combines a series of ML practices designed to handle the scarcity and imbalance of catalyst data. We believe that such insights can assist chemists in the development and identification of novel catalysts with superior performance.
arXiv Detail & Related papers (2024-07-10T13:09:53Z)
Beyond Major Product Prediction: Reproducing Reaction Mechanisms with Machine Learning Models Trained on a Large-Scale Mechanistic Dataset [10.968137261042715]
Mechanistic understanding of organic reactions can facilitate reaction development, impurity prediction, and in principle, reaction discovery. While several machine learning models have sought to address the task of predicting reaction products, their extension to predicting reaction mechanisms has been impeded by the lack of a corresponding mechanistic dataset. We construct such a dataset by imputing intermediates between experimentally reported reactants and products using expert reaction templates and train several machine learning models on the resulting dataset of 5,184,184 elementary steps.
arXiv Detail & Related papers (2024-03-07T15:26:23Z)
Retrosynthesis prediction enhanced by in-silico reaction data augmentation [66.5643280109899]
We present RetroWISE, a framework that employs a base model inferred from real paired data to perform in-silico reaction generation and augmentation. On three benchmark datasets, RetroWISE achieves the best overall performance against state-of-the-art models.
arXiv Detail & Related papers (2024-01-31T07:40:37Z)
Learning and Controlling Silicon Dopant Transitions in Graphene using Scanning Transmission Electron Microscopy [58.51812955462815]
We introduce a machine learning approach to determine the transition dynamics of silicon atoms on a single layer of carbon atoms. The data samples are processed and filtered to produce symbolic representations, which we use to train a neural network to predict transition probabilities. These learned transition dynamics are then leveraged to guide a single silicon atom throughout the lattice to pre-determined target destinations.
arXiv Detail & Related papers (2023-11-21T21:51:00Z)
Machine Learning for Polaritonic Chemistry: Accessing chemical kinetics [0.0]
We establish a framework based on a combination of machine learning (ML) models, trained using density-functional theory calculations, and molecular dynamics. We evaluate strong coupling, changes in reaction rate constant, and their influence on enthalpy and entropy for the deprotection reaction of 1-phenyl-2-trimethylsilylacetylene. While we find qualitative agreement with critical experimental observations, especially with regard to the changes in kinetics, we also find differences in comparison with previous theoretical predictions.
arXiv Detail & Related papers (2023-11-16T10:08:44Z)
Towards out-of-distribution generalizable predictions of chemical kinetics properties [61.15970601264632]
Out-Of-Distribution (OOD) kinetic property prediction is required to be generalizable. In this paper, we categorize the OOD kinetic property prediction into three levels (structure, condition, and mechanism) We create comprehensive datasets to benchmark the state-of-the-art ML approaches for reaction prediction in the OOD setting and the state-of-the-art graph OOD methods in kinetics property prediction problems.
arXiv Detail & Related papers (2023-10-04T20:36:41Z)
Improving Molecular Representation Learning with Metric Learning-enhanced Optimal Transport [49.237577649802034]
We develop a novel optimal transport-based algorithm termed MROT to enhance their generalization capability for molecular regression problems. MROT significantly outperforms state-of-the-art models, showing promising potential in accelerating the discovery of new substances.
arXiv Detail & Related papers (2022-02-13T04:56:18Z)
Unassisted Noise Reduction of Chemical Reaction Data Sets [59.127921057012564]
We propose a machine learning-based, unassisted approach to remove chemically wrong entries from data sets. Our results show an improved prediction quality for models trained on the cleaned and balanced data sets.
arXiv Detail & Related papers (2021-02-02T09:34:34Z)
Kinetics-Informed Neural Networks [0.0]
We use feed-forward artificial neural networks as basis functions for the construction of surrogate models to solve ordinary differential equations. We show that the simultaneous training of neural nets and kinetic model parameters in a regularized multiobjective optimization setting leads to the solution of the inverse problem. This surrogate approach to inverse kinetic ODEs can assist in the elucidation of reaction mechanisms based on transient data.
arXiv Detail & Related papers (2020-11-30T00:07:09Z)
Predictive modeling approaches in laser-based material processing [59.04160452043105]
This study aims to automate and forecast the effect of laser processing on material structures. The focus is centred on the performance of representative statistical and machine learning algorithms. Results can set the basis for a systematic methodology towards reducing material design, testing and production cost.
arXiv Detail & Related papers (2020-06-13T17:28:52Z)

This list is automatically generated from the titles and abstracts of the papers in this site.