Predicting the 3D microstructure of SOFC anodes from 2D SEM images using stochastic microstructure modeling and CNNs

TL;DR

This paper introduces a method that uses stochastic modeling and CNNs to predict 3D microstructures of SOFC anodes from 2D SEM images, reducing reliance on costly 3D imaging techniques.

Contribution

It presents a novel approach combining stochastic geometry and CNNs to reconstruct 3D microstructures from 2D SEM images, enabling efficient microstructure analysis.

Findings

The method accurately predicts 3D microstructure features.

The approach reduces the need for expensive 3D imaging.

Error analysis confirms the reliability of the predictions.

Abstract

The 3D microstructure of solid oxide fuel cell anodes significantly influences their electrochemical performance, but conventional methods for acquiring high-resolution microstructural 3D data such as focused ion beam scanning electron microscopy (FIB-SEM) are costly in both time and resources. In contrast, obtaining 2D images, such as from scanning electron microscopy (SEM), is more accessible, though typically providing insufficient information to accurately characterize the 3D microstructure. To address this challenge, we propose a novel approach that predicts the 3D microstructure from 2D SEM images. The presented method utilizes a low-parametric 3D model from stochastic geometry to generate a large number of virtual 3D microstructures and employs a physics-based SEM simulation tool to obtain the corresponding 2D SEM images. By systematically varying the underlying model parameters, a large dataset can be generated to train convolutional neural networks (CNNs). By doing so, we can statistically reconstruct the 3D microstructure from 2D SEM images by drawing realizations from the stochastic 3D model using the predicted model parameters. In addition, we conducted an error analysis on key geometrical descriptors to quantitatively evaluate the accuracy and reliability of this stereological prediction tool.