Saved in:
Bibliographic Details
Main Authors: Tran, Richard, Huang, Liqiang, Zi, Yuan, Wang, Shengguang, Comer, Benjain M., Wu, Xuqing, Raaijman, Stefan J., Sinha, Nishant K., Sadasivan, Sajanikumari, Thundiyil, Shibin, Mamtani, Kuldeep B., Iyer, Ganesh, Grabow, Lars C., Lu, Ligang, Chen, Jiefu
Format: Preprint
Published: 2023
Subjects:
Online Access:https://arxiv.org/abs/2311.00784
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910593068302336
author Tran, Richard
Huang, Liqiang
Zi, Yuan
Wang, Shengguang
Comer, Benjain M.
Wu, Xuqing
Raaijman, Stefan J.
Sinha, Nishant K.
Sadasivan, Sajanikumari
Thundiyil, Shibin
Mamtani, Kuldeep B.
Iyer, Ganesh
Grabow, Lars C.
Lu, Ligang
Chen, Jiefu
author_facet Tran, Richard
Huang, Liqiang
Zi, Yuan
Wang, Shengguang
Comer, Benjain M.
Wu, Xuqing
Raaijman, Stefan J.
Sinha, Nishant K.
Sadasivan, Sajanikumari
Thundiyil, Shibin
Mamtani, Kuldeep B.
Iyer, Ganesh
Grabow, Lars C.
Lu, Ligang
Chen, Jiefu
contents The efficiency of $H_2$ production via water electrolysis is typically limited to the sluggish oxygen evolution reaction (OER). As such, significant emphasis has been placed upon improving the rate of OER through the anode catalyst. More recently, the Open Catalyst 2022 (OC22) framework has provided a large dataset of density functional theory (DFT) calculations for OER intermediates on the surfaces of oxides. When coupled with state-of-the-art graph neural network models, total energy predictions can be achieved with a mean absolute error as low as 0.22 eV. In this work, we interpolated a database of the total energy predictions for all slabs and OER surface intermediates for 4,119 oxide materials in the original OC22 dataset using pre-trained models from the OC22 framework. This database includes all terminations of all facets up to a maximum Miller index of 1. To demonstrate the full utility of this database, we constructed a flexible screening framework to identify viable candidate anode catalysts for OER under varying reaction conditions for bulk, surface, and nanoscale Pourbaix stability as well as material cost, overpotential, and metastability. From our assessment, we were able to identify 122 and 68 viable candidates for OER under the bulk and nanoscale regime respectively.
format Preprint
id arxiv_https___arxiv_org_abs_2311_00784
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Rational design of nanoscale stabilized oxide catalysts for OER with OC22
Tran, Richard
Huang, Liqiang
Zi, Yuan
Wang, Shengguang
Comer, Benjain M.
Wu, Xuqing
Raaijman, Stefan J.
Sinha, Nishant K.
Sadasivan, Sajanikumari
Thundiyil, Shibin
Mamtani, Kuldeep B.
Iyer, Ganesh
Grabow, Lars C.
Lu, Ligang
Chen, Jiefu
Materials Science
The efficiency of $H_2$ production via water electrolysis is typically limited to the sluggish oxygen evolution reaction (OER). As such, significant emphasis has been placed upon improving the rate of OER through the anode catalyst. More recently, the Open Catalyst 2022 (OC22) framework has provided a large dataset of density functional theory (DFT) calculations for OER intermediates on the surfaces of oxides. When coupled with state-of-the-art graph neural network models, total energy predictions can be achieved with a mean absolute error as low as 0.22 eV. In this work, we interpolated a database of the total energy predictions for all slabs and OER surface intermediates for 4,119 oxide materials in the original OC22 dataset using pre-trained models from the OC22 framework. This database includes all terminations of all facets up to a maximum Miller index of 1. To demonstrate the full utility of this database, we constructed a flexible screening framework to identify viable candidate anode catalysts for OER under varying reaction conditions for bulk, surface, and nanoscale Pourbaix stability as well as material cost, overpotential, and metastability. From our assessment, we were able to identify 122 and 68 viable candidates for OER under the bulk and nanoscale regime respectively.
title Rational design of nanoscale stabilized oxide catalysts for OER with OC22
topic Materials Science
url https://arxiv.org/abs/2311.00784