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Dialysis01:15

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Dialysis is a diffusion-based purification process that separates analyte molecules from a complex matrix. This is accomplished by allowing molecules in the solution to pass through a semipermeable membrane into a liquid on the other side. The membrane is usually made of cellulose acetate or cellulose nitrate, and the second liquid must be miscible with the solution. Ions (e.g., chloride or sodium) or organic molecules (e.g., glucose) can pass through the membrane pores, which generally have...
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Nanostructure-Informed Multiscale Modeling of Degradation Effects on Proton Conductivity in Nafion Membranes.

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Explainable Machine Learning and Deep Learning Models for Understanding Operational and Degradation Effects in Nafion

Xingyu Zhang1,2, Diego E Galvez-Aranda1,2, Robert Pöschl3

  • 1Laboratoire de Réactivité et de Chimie des Solides (LRCS), Université de Picardie Jules Verne, Hub de l'Energie, UMR CNRS 7314, 15 rue Baudelocque, 80039 Amiens Cedex, France.

ACS Applied Materials & Interfaces
|April 23, 2026
PubMed
Summary
This summary is machine-generated.

Machine learning models predict proton transport in Nafion membranes, crucial for fuel cell reliability. AI frameworks link degradation, temperature, and water content to conduction, enabling optimized membrane design.

Keywords:
degradation modelingmachine learningmembranepolymer electrolyte membrane fuel cellsproton conduction

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Area of Science:

  • Materials Science
  • Chemical Engineering
  • Computational Science

Background:

  • Proton transport in Nafion membranes is vital for proton exchange membrane fuel cell (PEMFC) performance.
  • Chemical degradation significantly impacts membrane reliability and longevity.
  • Predictive modeling of transport properties under various conditions is needed.

Purpose of the Study:

  • Develop interpretable Machine Learning (ML) and Deep Learning (DL) frameworks.
  • Predict key transport properties (conductivity, tortuosity) under varying conditions.
  • Understand how chemical degradation affects proton transport.

Main Methods:

  • Utilized a high-fidelity, multiscale simulation dataset.
  • Trained a 3D convolutional neural network on voxelized nanostructure data.
  • Applied Gradient-weighted Class Activation Mapping and Shapley-value analysis.
  • Developed random forest models with extracted geometric and macroscopic features.

Main Results:

  • Accurately predicted vehicular and Grotthuss conductivities and tortuosity.
  • Identified key nanostructural regions influencing proton conduction.
  • Quantified the impact of nanostructural and environmental factors on transport.
  • Constructed a mechanism map linking hydration, temperature, and degradation to conduction regimes.

Conclusions:

  • AI frameworks can capture geometry and semantics for materials analysis.
  • Nanostructure aging reshapes proton conduction pathways.
  • Developed a foundation for degradation-aware optimization and inverse design of membranes.
  • Opened new avenues for predictive aging modeling in ion-conducting membranes.