TY - GEN
T1 - From 2D to 3D
T2 - 43rd International Conference of the Chilean Computer Science Society, SCCC 2024
AU - Espinoza-Andaluz, Mayken
AU - Avila, Joseph
AU - Barzola-Monteses, Julio
AU - Andersson, Martin
N1 - Publisher Copyright:
© 2024 IEEE.
PY - 2024
Y1 - 2024
N2 - A fuel cell is an electrochemical device that transforms chemical energy into electrical energy and heat. It occurs through a controlled chemical reaction. Among its essential components are the porous electrodes, which play a pivotal role in the operation of the fuel cells. These electrodes are crucial because they facilitate the efficient flow of reactants to the reaction sites, thereby driving the energy conversion process. The electrodes are made of porous materials characterized by intricate and varied microstructures. Given the complexity of these structures and the significant cost associated with experimental equipment, it is highly beneficial to perform computational studies as a preliminary step. This study focuses on reconstructing a reliable three-dimensional (3D) volume of porous electrodes from two-dimensional (2D) images. Such a reconstruction is essential for conducting predictive analyses of the electrodes' experimental performance and behavior. The study examines key microstructural parameters, including porosity, tortuosity, and diffusivity. The results of employing advanced computational techniques illustrate that the proposed methodology is highly effective and robust for generating accurate 3D reconstructions from 2D images. This capability offers significant advantages for understanding and optimizing the performance of fuel cell electrodes before embarking on costly experimental trials.
AB - A fuel cell is an electrochemical device that transforms chemical energy into electrical energy and heat. It occurs through a controlled chemical reaction. Among its essential components are the porous electrodes, which play a pivotal role in the operation of the fuel cells. These electrodes are crucial because they facilitate the efficient flow of reactants to the reaction sites, thereby driving the energy conversion process. The electrodes are made of porous materials characterized by intricate and varied microstructures. Given the complexity of these structures and the significant cost associated with experimental equipment, it is highly beneficial to perform computational studies as a preliminary step. This study focuses on reconstructing a reliable three-dimensional (3D) volume of porous electrodes from two-dimensional (2D) images. Such a reconstruction is essential for conducting predictive analyses of the electrodes' experimental performance and behavior. The study examines key microstructural parameters, including porosity, tortuosity, and diffusivity. The results of employing advanced computational techniques illustrate that the proposed methodology is highly effective and robust for generating accurate 3D reconstructions from 2D images. This capability offers significant advantages for understanding and optimizing the performance of fuel cell electrodes before embarking on costly experimental trials.
KW - Complex Materials
KW - Diffusion Parameters
KW - Digital Reconstruction
KW - Porous Materials
UR - https://www.scopus.com/pages/publications/85213516838
U2 - 10.1109/SCCC63879.2024.10767606
DO - 10.1109/SCCC63879.2024.10767606
M3 - Paper in conference proceeding
AN - SCOPUS:85213516838
T3 - Proceedings - International Conference of the Chilean Computer Science Society, SCCC
SP - 1
EP - 7
BT - 2024 43rd International Conference of the Chilean Computer Science Society, SCCC
PB - IEEE Computer Society
Y2 - 28 October 2024 through 30 October 2024
ER -