2022
DOI: 10.1016/j.dche.2021.100009
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A review of automated and data-driven approaches for pathway determination and reaction monitoring in complex chemical systems

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Cited by 11 publications
(14 citation statements)
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“…However, in the context of online reaction monitoring, sophisticated spectroscopic curve resolution algorithms can be used to project real-time spectra onto the temporal data collection mode and the spectroscopic channels, which in accordance with Beer’s law, gain interpretability as the pseudo-component concentrations and pseudo-component spectra, respectively. The kinetics of the underlying chemical transformations can then be assessed from the temporal concentration projections to further facilitate control and optimization . The automated mapping of the hypothesized reaction networks to domain knowledge-based real chemistries can aid the future development of an interpretable end-to-end pipeline to identify species, reactions, and kinetics from spectroscopic data.…”
Section: Discussionmentioning
confidence: 99%
“…However, in the context of online reaction monitoring, sophisticated spectroscopic curve resolution algorithms can be used to project real-time spectra onto the temporal data collection mode and the spectroscopic channels, which in accordance with Beer’s law, gain interpretability as the pseudo-component concentrations and pseudo-component spectra, respectively. The kinetics of the underlying chemical transformations can then be assessed from the temporal concentration projections to further facilitate control and optimization . The automated mapping of the hypothesized reaction networks to domain knowledge-based real chemistries can aid the future development of an interpretable end-to-end pipeline to identify species, reactions, and kinetics from spectroscopic data.…”
Section: Discussionmentioning
confidence: 99%
“…Contemporary computational chemistry has reached a stage at which massive exploration into chemical reaction space with an unprecedented resolution with respect to the number of potentially relevant molecular structures is becoming a realistic task. Various algorithmic advances have shown that extensive structural screenings can nowadays be automated and carried out using modern computational chemistry protocols. Automated computational strategies for predicting multistep reaction mechanisms for complex chemical processes, such as pyrolysis, combustion, or catalytic transformations, offer substantial advantages over the conventional strategy largely based on the expert-guided exploration of selected and restricted number of mechanistic alternatives.…”
Section: Introductionmentioning
confidence: 99%
“…A conventional workflow in applied computational catalysis studies approaches this task via manual structural explorations, which rely largely on the expert knowledge and a substantial amount of chemical intuition, thus limiting the study to the expected reactivity domains. The last decade has seen a rapid development of various computational approaches to automate the exploration and discovery of complex chemical reaction networks, targeting the reconstruction of a complete atomistic representation of the mechanism of a chemical conversion process. Strategies for the accelerated exploration of reaction networks can vary substantially in the computational costs as well as the comprehensiveness and accuracy of the chemical reaction network that they produce. , …”
Section: Introductionmentioning
confidence: 99%
“…Various algorithmic advances have shown that extensive structural screenings can nowadays be automated and carried out using modern computational chemistry protocols. [1][2][3][4][5] Automated computational strategies for predicting multi-step reaction mechanisms for complex chemical processes such as pyrolysis, combustion or catalytic transformations offer substantial advantages over the conventional strategy largely based on the expert-guided exploration of selected and restricted number of mechanistic alternatives.…”
Section: Introductionmentioning
confidence: 99%
“…The last decade has seen a rapid development of various computational approaches to automate the exploration and discovery of complex chemical reaction networks targeting the reconstruction of a complete atomistic representation of the mechanism of a chemical conversion process. [1][2][3][4][5] Strategies for the accelerated exploration of reaction networks can vary substantially in the computational costs as well as the comprehensiveness and accuracy of the chemical reaction network that they produce. 19,20 For example, the Global Reaction Route Mapping (GRRM) approach introduced by Maeda et al, 21 in which starting from a given "reactant" configuration, the PES is explored to discover new transition states and intermediates forming the reaction network.…”
Section: Introductionmentioning
confidence: 99%