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Main Authors: Chen, Haotian, Huang, Chenyang, Rodríguez, Alexander, Mistry, Aashutosh, Viswanathan, Venkatasubramanian
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.11631
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author Chen, Haotian
Huang, Chenyang
Rodríguez, Alexander
Mistry, Aashutosh
Viswanathan, Venkatasubramanian
author_facet Chen, Haotian
Huang, Chenyang
Rodríguez, Alexander
Mistry, Aashutosh
Viswanathan, Venkatasubramanian
contents Despite the long history of electrochemistry, there is a lack of quantitative algorithms that rigorously correlate experiment with theory. Electrochemical modeling has had advanced across empirical, analytical, numerical, and data-driven paradigms. Data-driven machine learning and physics based electrochemical modeling, however, have not been explicitly linked. Here we introduce Differentiable Electrochemistry, a mew paradigm in electrochemical modeling that integrates thermodynamics, kinetics and mass transport with differentiable programming enabled by automatic differentiation. By making the entire electrochemical simulation end-to-end differentiable, this framework enables gradient-based optimization for mechanistic discovery from experimental and simulation data, achieving approximately one to two orders of improvement over gradient-free methods. We develop a rich repository of differentiable simulators across diverse mechanisms, and apply Differentiable Electrochemistry to bottleneck problems in kinetic analysis. Specifically, Differentiable Electrochemistry advances beyond Tafel and Nicholson method by removing several limitations including Tafel region selection, and identifies the electron transfer mechanism in Li metal electrodeposition/stripping by parameterizing the full Marcus-Hush-Chidsey formalism. In addition, Differentiable Electrochemistry interprets Operando X-ray measurements in concentrated electrolyte by coupling concentration and velocity theories. This framework resolves ambiguity when multiple electrochemical theories intertwine, and establishes a physics-consistent and data-efficient foundation for predictive electrochemical modeling.
format Preprint
id arxiv_https___arxiv_org_abs_2511_11631
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Differentiable Electrochemistry: A paradigm for uncovering hidden physical phenomena in electrochemical systems
Chen, Haotian
Huang, Chenyang
Rodríguez, Alexander
Mistry, Aashutosh
Viswanathan, Venkatasubramanian
Chemical Physics
Despite the long history of electrochemistry, there is a lack of quantitative algorithms that rigorously correlate experiment with theory. Electrochemical modeling has had advanced across empirical, analytical, numerical, and data-driven paradigms. Data-driven machine learning and physics based electrochemical modeling, however, have not been explicitly linked. Here we introduce Differentiable Electrochemistry, a mew paradigm in electrochemical modeling that integrates thermodynamics, kinetics and mass transport with differentiable programming enabled by automatic differentiation. By making the entire electrochemical simulation end-to-end differentiable, this framework enables gradient-based optimization for mechanistic discovery from experimental and simulation data, achieving approximately one to two orders of improvement over gradient-free methods. We develop a rich repository of differentiable simulators across diverse mechanisms, and apply Differentiable Electrochemistry to bottleneck problems in kinetic analysis. Specifically, Differentiable Electrochemistry advances beyond Tafel and Nicholson method by removing several limitations including Tafel region selection, and identifies the electron transfer mechanism in Li metal electrodeposition/stripping by parameterizing the full Marcus-Hush-Chidsey formalism. In addition, Differentiable Electrochemistry interprets Operando X-ray measurements in concentrated electrolyte by coupling concentration and velocity theories. This framework resolves ambiguity when multiple electrochemical theories intertwine, and establishes a physics-consistent and data-efficient foundation for predictive electrochemical modeling.
title Differentiable Electrochemistry: A paradigm for uncovering hidden physical phenomena in electrochemical systems
topic Chemical Physics
url https://arxiv.org/abs/2511.11631