Characterizing Grain Boundary Effects on Mg<sup>2+</sup> Conduction in Metal–Organic Frameworks

Wang, Yan; Luo, Tongtong; Elander, Brooke; Mu, Yu; Wang, Dunwei; Mohanty, Udayan; Bao, Junwei Lucas

doi:10.1021/acsami.3c02329

Cited by 8 publications

(2 citation statements)

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“…To assess our methods for TS search in large-scale periodic bulk-phase structures, we use a data set of ion and small-molecule migrations in Mg-MOF-74 (Figure ). Specifically, we calculate transport pathways for S 2 , S 2 – , Br 3 , Br 3 – , MgBr 2 , and bis(trifluoromethane)sulfonimide (TFSI – ) in Mg-MOF-74, which has been previously studied as an ion conductor for energy storage applications. − All species, except MgBr 2 , bind to Mg open metal sites of MOF and migrate along the direction of the MOF pore (Figure ). MgBr 2 binds to dimethoxyethane solvent molecules immobilized inside MOF.…”

Section: Computational Detailsmentioning

confidence: 99%

Physical Prior Mean Function-Driven Gaussian Processes Search for Minimum-Energy Reaction Paths with a Climbing-Image Nudged Elastic Band: A General Method for Gas-Phase, Interfacial, and Bulk-Phase Reactions

Teng,

Wang,

Bao

2024

J. Chem. Theory Comput.

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The climbing-image nudged elastic band (CI-NEB) method serves as an indispensable tool for computational chemists, offering insight into minimum-energy reaction paths (MEPs) by delineating both transition states (TSs) and intermediate nonstationary structures along reaction coordinates. However, executing CI-NEB calculations for reactions with extensive reaction coordinate spans necessitates a large number of images to ensure a reliable convergence of the MEPs and TS structures, presenting a computationally demanding optimization challenge, even with mildly costly electronic-structure methods. In this study, we advocate for the utilization of physically inspired prior mean function-based Gaussian processes (GPs) to expedite MEP exploration and TS optimization via the CI-NEB method. By incorporating reliable prior physical approximations into potential energy surface (PES) modeling, we demonstrate enhanced efficiency in multidimensional CI-NEB optimization with surrogate-based optimizers. Our physically informed GP approach not only outperforms traditional nonsurrogate-based optimizers in optimization efficiency but also on-the-fly learns the reaction path valley during optimization, culminating in significant advancements. The surrogate PES derived from our optimization exhibits high accuracy compared to true PES references, aligning with our emphasis on leveraging reliable physical priors for robust and efficient posterior mean learning in GPs. Through a systematic benchmark study encompassing various reaction pathways, including gas-phase, bulk-phase, and interfacial/surface reactions, our physical GPs consistently demonstrate superior efficiency and reliability. For instance, they outperform the popular fast inertial relaxation engine optimizer by approximately a factor of 10, showcasing their versatility and efficacy in exploring reaction mechanisms and surface reaction PESs.

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Section: Computational Detailsmentioning

confidence: 99%

Physical Prior Mean Function-Driven Gaussian Processes Search for Minimum-Energy Reaction Paths with a Climbing-Image Nudged Elastic Band: A General Method for Gas-Phase, Interfacial, and Bulk-Phase Reactions

Teng,

Wang,

Bao

2024

J. Chem. Theory Comput.

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“…Solvation plays an important role in a wide range of extended structures, including surface-catalyzed reactions, , porous crystalline materials, − and nanocrystals in solution . Thus, the modeling of solvation effects is crucial for an accurate understanding of physical processes in these systems.…”

Section: Introductionmentioning

confidence: 99%

PW-SMD: A Plane-Wave Implicit Solvation Model Based on Electron Density for Surface Chemistry and Crystalline Systems in Aqueous Solution

Wang,

Teng,

Begin

et al. 2024

J. Chem. Theory Comput.

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Electron density-based implicit solvation models are a class of techniques for quantifying solvation effects and calculating free energies of solvation without an explicit representation of solvent molecules. Integral to the accuracy of solvation modeling is the proper definition of the solvation shell separating the solute molecule from the solvent environment, allowing for a physical partitioning of the free energies of solvation. Unlike state-of-the-art implicit solvation models for molecular quantum chemistry calculations, e.g., the solvation model based on solute electron density (SMD), solvation models for systems under periodic boundary conditions with plane-wave (PW) basis sets have been limited in their accuracy. Furthermore, a unified implicit solvation model with both homogeneous solution-phase and heterogeneous interfacial structures treated on equal footing is needed. In order to address this challenge, we developed a highaccuracy solvation model for periodic PW calculations that is applicable to molecular, ionic, interfacial, and bulk-phase chemistry. Our model, PW-SMD, is an extension of the SMD molecular solvation model to periodic systems in water. The free energy of solvation is partitioned into the electrostatic and cavity−dispersion−solvent structure (CDS) contributions. The electrostatic contributions of the solvation shell surrounding solute structures are parametrized based on their geometric and physical properties. In addition, the nonelectrostatic contribution to the solvation energy is accounted for by extending the CDS formalism of SMD to incorporate periodic boundary conditions. We validate the accuracy and robustness of our solvation model by comparing predicted solvation free energies against experimental data for molecular and ionic systems, carved-cluster composite energetic models of solvated reaction energies and barriers on surface systems, and deep-learning-accelerated ab initio molecular dynamics (AIMD). Our developed periodic implicit solvation model shows significantly improved accuracy compared to previous work (namely, solvation models in aqueous solution) and can be applied to simulate solvent effects in a wide range of surface and crystalline materials.

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Polysulfides in Magnesium‐Sulfur Batteries

Luo,

Wang,

Elander

et al. 2023

Advanced Materials

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Mg‐S batteries hold great promise as a potential alternative to Li‐based technologies. Their further development hinges on solving a few key challenges, including the lower capacity and poorer cycling performance when compared to Li counterparts. At the heart of the issues is the lack of knowledge on polysulfide chemical behaviors in the Mg‐S battery environment. In this Review, we provide a comprehensive overview of the current understanding of polysulfide behaviors in Mg‐S batteries. First, we provide a systematic summary of experimental and computational techniques for polysulfide characterization. Next, conversion pathways for Mg polysulfide species within the battery environment are discussed, highlighting the important role of polysulfide solubility in determining reaction kinetics and overall battery performance. The focus then shifts to negative effects of polysulfide shuttling on Mg‐S batteries. We outline various strategies for achieving an optimal balance between polysulfide solubility and shuttling, including use of electrolyte additives, polysulfide‐trapping materials, and dual‐functional catalysts. Based on the current understanding, we identify directions for further advancing knowledge of Mg polysulfide chemistry, emphasizing the integration of experiment with computation as a powerful approach to accelerate the development of Mg‐S battery technology.This article is protected by copyright. All rights reserved

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Characterizing Grain Boundary Effects on Mg²⁺ Conduction in Metal–Organic Frameworks

Cited by 8 publications

References 76 publications

Physical Prior Mean Function-Driven Gaussian Processes Search for Minimum-Energy Reaction Paths with a Climbing-Image Nudged Elastic Band: A General Method for Gas-Phase, Interfacial, and Bulk-Phase Reactions

Physical Prior Mean Function-Driven Gaussian Processes Search for Minimum-Energy Reaction Paths with a Climbing-Image Nudged Elastic Band: A General Method for Gas-Phase, Interfacial, and Bulk-Phase Reactions

PW-SMD: A Plane-Wave Implicit Solvation Model Based on Electron Density for Surface Chemistry and Crystalline Systems in Aqueous Solution

Polysulfides in Magnesium‐Sulfur Batteries

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Characterizing Grain Boundary Effects on Mg2+ Conduction in Metal–Organic Frameworks

Cited by 8 publications

References 76 publications

Physical Prior Mean Function-Driven Gaussian Processes Search for Minimum-Energy Reaction Paths with a Climbing-Image Nudged Elastic Band: A General Method for Gas-Phase, Interfacial, and Bulk-Phase Reactions

Physical Prior Mean Function-Driven Gaussian Processes Search for Minimum-Energy Reaction Paths with a Climbing-Image Nudged Elastic Band: A General Method for Gas-Phase, Interfacial, and Bulk-Phase Reactions

PW-SMD: A Plane-Wave Implicit Solvation Model Based on Electron Density for Surface Chemistry and Crystalline Systems in Aqueous Solution

Polysulfides in Magnesium‐Sulfur Batteries

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Characterizing Grain Boundary Effects on Mg²⁺ Conduction in Metal–Organic Frameworks