Calibrating DFT Formation Enthalpy Calculations by Multifidelity Machine Learning

Gong, Sheng; Wang, Shuo; Xie, Tian; Chae, Woo Hyun; Liu, Runze; Shao‐Horn, Yang; Grossman, Jeffrey C.

doi:10.1021/jacsau.2c00235

Cited by 27 publications

(20 citation statements)

References 101 publications

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“…We note that the magnitude of the thermodynamic competition scale (tens of meV/atom) in aqueous solution-based synthesis is smaller than the thermodynamic limit for the synthesis of metastable inorganic materials (more than one hundred meV/atom) [11], and might be comparable with DFT errors [38,39,40].…”

Section: Discussionmentioning

confidence: 78%

Optimal thermodynamic conditions to minimize kinetic byproducts in aqueous materials synthesis

Wang

Sun

Cruse

et al. 2023

Preprint

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Thermodynamics has strong predictive power for materials synthesis by identifying the stability region of target phases, but does not give explicit information about the relative competitiveness of undesired byproduct phases in synthesis. In this work, we propose a quantitative and computable measure to guide the selection of synthesis conditions. Defining thermodynamic competition as the difference in driving force between a target phase and its competing phases, we hypothesize that phase-pure synthesis becomes more likely when this thermodynamic competition is minimized. We systematically validate this hypothesis with two approaches: (1) we analyze large-scale solution synthesis procedures as text-mined from the literature, and show that experimentally-optimized synthesis conditions are near the predicted thermodynamic optimum point, and (2) direct experimental evaluation of synthesis in LiIn(IO3)4 and LiFePO4, which show that phase-pure synthesis occurs only when thermodynamic competition is minimized. Our work demonstrates that a quantitative assessment of thermodynamic competition is an effective descriptor for synthesis optimization and a promising tool for optimizing aqueous solution-based experimental synthesis conditions.

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Section: Discussionmentioning

confidence: 78%

Optimal thermodynamic conditions to minimize kinetic byproducts in aqueous materials synthesis

Wang

Sun

Cruse

et al. 2023

Preprint

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“…Recently, multi-fidelity learning has been successfully applied to chemistry and materials science. Several cases, including the prediction of formation enthalpy, 52 bandgap, 53–55 and energies, 56,57 are available in the literature.…”

Section: Resultsmentioning

confidence: 99%

Discovery of thermosetting polymers with low hygroscopicity, low thermal expansivity, and high modulus by machine learning

Zhao

et al. 2023

J. Mater. Chem. A

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“…On the other hand, other relevant properties need to be calculated, such as performance on adsorption/storage of common gas molecules, partial atomic charges normally used to interpret trends while modeling chemical reactions, and density of states/band structures, which reveal detailed charge transport pathways. Machine learning techniques have also shown great promise in materials science research for the prediction of formation energies, adsorption energies, , band gap values, and designing new materials . The created crystal structures and their calculated property data gathered in our EC-MOF/Phase-I database provide an ideal data set for applying various machine learning techniques in order to explore their potentials for different applications.…”

Section: Future Workmentioning

confidence: 99%

In Silico High-Throughput Design and Prediction of Structural and Electronic Properties of Low-Dimensional Metal–Organic Frameworks

Zhang

Valente

Shi

et al. 2023

ACS Appl. Mater. Interfaces

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The advent of π-stacked layered metal–organic frameworks (MOFs), which offer electrical conductivity on top of permanent porosity and high surface area, opened up new horizons for designing compact MOF-based devices such as battery electrodes, supercapacitors, and spintronics. Permutation of structural building blocks, including metal nodes and organic linkers, in these electrically conductive (EC) materials, results in new systems with unprecedented and unexplored physical and chemical properties. With the ultimate goal of providing a platform for accelerated material design and discovery, here we lay the foundations for the creation of the first comprehensive database of EC-MOFs with an experimentally guided approach. The first phase of this database, coined EC-MOF/Phase-I, is composed of 1,057 bulk and monolayer structures built by all possible combinations of experimentally reported organic linkers, functional groups, and metal nodes. A high-throughput screening (HTS) workflow is constructed to implement density functional theory calculations with periodic boundary conditions to optimize the structures and calculate some of their most relevant properties. Because research and development in the area of EC-MOFs has long been suffering from the lack of appropriate initial crystal structures, all of the geometries and property data have been made available for the use of the community through an online platform that was developed during the course of this work. This database provides comprehensive physical and chemical data of EC-MOFs as well as the convenience of selecting appropriate materials for specific applications, thus accelerating the design and discovery of EC-MOF-based compact devices.

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Calibrating DFT Formation Enthalpy Calculations by Multifidelity Machine Learning

Cited by 27 publications

References 101 publications

Optimal thermodynamic conditions to minimize kinetic byproducts in aqueous materials synthesis

Optimal thermodynamic conditions to minimize kinetic byproducts in aqueous materials synthesis

Discovery of thermosetting polymers with low hygroscopicity, low thermal expansivity, and high modulus by machine learning

In Silico High-Throughput Design and Prediction of Structural and Electronic Properties of Low-Dimensional Metal–Organic Frameworks

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