Traversing Dense Networks of Elementary Chemical Reactions to Predict Minimum‐Energy Reaction Mechanisms

Robertson, Christopher; Ismail, Idil; Habershon, Scott

doi:10.1002/syst.201900047

Cited by 18 publications

(23 citation statements)

References 63 publications

(130 reference statements)

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“…However, as described above, these algo-rithms will not necessarily produce chemically valid pathways in networks containing multi-reactant reactions. It has historically been necessary to use custom methods that have suboptimal performance and scale poorly with network size based on tree traversal algorithms 22 , breadth-first-search 25 , or depth-firstsearch 11,25 . Performant stochastic sampling approaches can instead be employed, 30 but they are not guaranteed to find the true best solution(s).…”

Section: Solutionmentioning

confidence: 99%

“…Instead, researchers employ custom approaches that can calculate path costs while respecting reaction stoichiometry. 25 These algorithms suffer from performance and scaling limitations 11,25 that have historically made it necessary to significantly restrict network size. As a result, reaction networks have not previously been applied to complex electrochemical or photochemical systems which may include thousands of species and millions of reactions.…”

Section: Introductionmentioning

confidence: 99%

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A Chemically Consistent Graph Architecture for Massive Reaction Networks Applied to Solid-Electrolyte Interphase Formation

Blau

Patel²,

Spotte-Smith³

et al. 2020

Preprint

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Modeling reactivity with chemical reaction networks could yield fundamental mechanistic understanding that would expedite the development of processes and technologies for energy storage, medicine, catalysis, and more. Thus far, reaction networks have been limited in size by chemically inconsistent graph representations of multi-reactant reactions (e.g. A + B reacts to C) that cannot enforce stoichiometric constraints, precluding the use of optimized shortest-path algorithms. Here, we report a chemically consistent graph architecture that overcomes these limitations using a novel multi-reactant representation and iterative cost-solving procedure. Our approach enables the identification of all low-cost pathways to desired products in massive reaction networks containing reactions of any stoichiometry, allowing for the investigation of vastly more complex systems than previously possible. Leveraging our architecture, we construct the first ever electrochemical reaction network from first-principles thermodynamic calculations to describe the formation of the Li-ion solid electrolyte interphase (SEI), which is critical for passivation of the negative electrode. Using this network comprised of nearly 6,000 species and 4.5 million reactions, we interrogate the formation of a key SEI component, lithium ethylene dicarbonate. We automatically identify previously proposed mechanisms as well as multiple novel pathways containing counter-intuitive reactions that have not, to our knowledge, been reported in the literature. We envision that our framework and data-driven methodology will facilitate efforts to engineer the composition-related properties of the SEI - or of any complex chemical process - through selective control of reactivity.

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Section: Solutionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Chemically Consistent Graph Architecture for Massive Reaction Networks Applied to Solid-Electrolyte Interphase Formation

Blau

Patel²,

Spotte-Smith³

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

Section: Introductionmentioning

confidence: 99%

A chemically consistent graph architecture for massive reaction networks applied to solid-electrolyte interphase formation

et al. 2021

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“…However, several very promising methodologies have been developed to automate the discovery of reaction mechanisms using QM. [1,2,3,4,5,6,7,8,9,10,11] Following Dewyer et al [11] these methods can be categorized into four categories: 1) encoding mechanistic steps, 2) generate transition state (TS) guesses, 3) generate intermediates using graph theory, and 4) generate driving coordinates. Subsequently, Grimme introduced a meta-dynamics approach [9] that arguably represents a fifth category and Lavigne et al [10] have recently combined this approach with a driving coordinate approach.…”

Section: Introductionmentioning

confidence: 99%

Fast and Automated Identification of Reactions with Low Barriers: The Decomposition of 3-Hydroperoxypropanal

Rasmussen¹,

Madsen²,

Jensen

2021

Preprint

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<div> <div> <div> <p>We show how fast semiempirical QM methods can be used to significantly decrease the CPU requirements for automated reaction mechanism discovery, using two different method for generating reaction products: graph-based systematic enumeration of all possible products and the meta-dynamics approach by Grimme (<i>J. Chem. Theory. Comput</i>. 2019, 15, 2847). We test the two approaches on the low-barrier reactions of 3-hydroperoxypropanal, which have been studied by a large variety of reaction discovery approaches and therefore provides a good benchmark. By using PM3 and GFN2-xTB for reaction energy and barrier screening the systematic approach identifies 64 reactions (out of 27,577 possible reactions) for DFT refinement, which in turn identifies the three reactions with lowest barriers plus a previously undiscovered reaction. With optimised hyperparameters meta-dynamics followed by PM3/GFN2-xTB-based screening identifies 15 reactions for DFT refinement, which in turn identifies the three reactions with lowest barrier. The number of DFT refinements can be further reduced to as little as six for both approaches by first verifying the transition states with GFN1-xTB. The main conclusion is that the semiempirical methods are accurate and fast enough to automatically identify promising candidates for DFT refinement for the low barrier reactions of 3-hydroperoxypropanal in a few hours using modest computational resources. </p> </div> </div> </div>

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Traversing Dense Networks of Elementary Chemical Reactions to Predict Minimum‐Energy Reaction Mechanisms

Cited by 18 publications

References 63 publications

A Chemically Consistent Graph Architecture for Massive Reaction Networks Applied to Solid-Electrolyte Interphase Formation

A Chemically Consistent Graph Architecture for Massive Reaction Networks Applied to Solid-Electrolyte Interphase Formation

A chemically consistent graph architecture for massive reaction networks applied to solid-electrolyte interphase formation

Fast and Automated Identification of Reactions with Low Barriers: The Decomposition of 3-Hydroperoxypropanal

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