April 22 - 26, 2024
Seattle, Washington
May 7 - 9, 2024 (Virtual)
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2024 MRS Spring Meeting & Exhibit
MT01.09.14

Understanding The Interplay between Anion Dynamics and Proton Conduction in Solid-Acid Compounds Using Machine Learning Molecular Dynamics

When and Where

Apr 25, 2024
5:00pm - 7:00pm
Flex Hall C, Level 2, Summit

Presenter(s)

Co-Author(s)

Menghang (David) Wang1,Cameron Owen1,Grace Xiong2,Jingxuan Ding1,Yu Xie1,Simon Batzner1,Albert Musaelian1,Anders Johansson1,Nicola Molinari1,Ni Zhan3,Ryan Adams3,Sossina Haile2,Boris Kozinsky1

Harvard University1,Northwestern University2,Princeton University3

Abstract

Menghang (David) Wang1,Cameron Owen1,Grace Xiong2,Jingxuan Ding1,Yu Xie1,Simon Batzner1,Albert Musaelian1,Anders Johansson1,Nicola Molinari1,Ni Zhan3,Ryan Adams3,Sossina Haile2,Boris Kozinsky1

Harvard University1,Northwestern University2,Princeton University3
Solid acid materials play a pivotal role as electrolytes for intermediate temperature hydrogen fuel cells. However, our current understanding of the relevant atomic motions that govern proton conduction remains incomplete, necessitating further investigation in different solid acid compounds. It is imperative to explore the atomic-scale correlation between anion and proton dynamics to design novel solid acid compounds with high proton conductivity.<br/><br/>In the superprotonic phase, solid acid proton conductors exhibit intricate behaviors, characterized by local proton hops in the O-H...O bond and anion reorientation. These phenomena comprise a two-step process necessary for long-range proton motion. Existing computational studies treat anion and proton dynamics as independent processes, while we find strong correlations between anion and proton dynamics in both CsH<sub>2</sub>PO<sub>4</sub> (CDP) and CsHSO<sub>4</sub> (CHS) from machine learning molecular dynamics over nanosecond timescales. Achieving a nanosecond timescale is crucial to comprehensively study the diffusive regime. We observe that not all anion reorientations contribute to long-range proton motion, underscoring its multifaceted role in superprotonic behavior. Additionally, the contribution of anion reorientations to long-range proton motion exhibits distinctive characteristics in CDP and CHS. Furthermore, we confirm a significant O-H reorientation preceding the long-range proton motion, substantiating a previously hypothesized but unverified process. Our approach leverages machine learning interatomic force fields (MLFFs) developed through uncertainty-aware active learning [1] and equivariant neural networks [2]. By combining ab-initio precision with simulations of thousands of atoms over nanosecond timescales, our MLFFs support our findings on the correlations of anion dynamics and the long-range proton transfer with sufficient statistics.<br/><br/>This work bridges crucial knowledge gaps in the superprotonic behavior of solid acid proton conductors and has the potential to inform the design of advanced solid acid compounds for renewable energy technologies.<br/><br/>[1] Xie, Y., Vandermause, J., Ramakers, S. et al. Uncertainty-aware molecular dynamics from Bayesian active learning for phase transformations and thermal transport in SiC. npj Comput Mater 9, 36 (2023).<br/>[2] A. Musaelian, S. Batzner, A. Johansson, L. Sun, C. Owen, M. Kornbluth, and B. Kozinsky, Learning local equivariant representations for large-scale atomistic dynamics Nat. Commun., 14, 579 (2023)

Keywords

diffusion

Symposium Organizers

Raymundo Arroyave, Texas A&M Univ
Elif Ertekin, University of Illinois at Urbana-Champaign
Rodrigo Freitas, Massachusetts Institute of Technology
Aditi Krishnapriyan, UC Berkeley

Session Chairs

Chris Bartel
Rodrigo Freitas
Sara Kadkhodaei
Wenhao Sun

In this Session