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Main Authors: Lei, Wenhai, Yang, Yuankai, Yang, Shuo, Zhang, Ge, Poonoosamy, Jenna, Juel, Anne, Meheust, Yves, Bagheria, Shervin, Wang, Moran
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2503.04180
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author Lei, Wenhai
Yang, Yuankai
Yang, Shuo
Zhang, Ge
Poonoosamy, Jenna
Juel, Anne
Meheust, Yves
Bagheria, Shervin
Wang, Moran
author_facet Lei, Wenhai
Yang, Yuankai
Yang, Shuo
Zhang, Ge
Poonoosamy, Jenna
Juel, Anne
Meheust, Yves
Bagheria, Shervin
Wang, Moran
contents The transition to a sustainable, low-carbon energy future requires transformative advancements in energy and environmental technologies. Carbon capture and sequestration, underground hydrogen storage, and nuclear waste geological disposal will be central aspects of a sustainable energy future, both for mitigating CO2 emissions and providing green energy. A comprehensive understanding of multiphase flow through porous media, along with reactive transport and microbial activities, is essential for assessing the feasibility and managing the risks of these technologies. Microfluidic porous media platforms have emerged as powerful tools for the direct visualization of multiphase reactive flow in porous media and eventually optimizing these multiple physicochemical and biological processes. This review highlights critical scientific challenges associated with these sustainable energy solutions and summarizes the state-of-the-art microfluidic techniques for studying the interplay between multiphase flow, reactive transport, and biological effects in porous media. We provide a comprehensive overview of how these microfluidic approaches enhance the understanding of fundamental pore-scale dynamics and bridge the gap between pore-scale events and large-scale processes. This review is expected to promote both experimental and theoretical understanding of multiphase reactive flow in porous media, thereby informing material design, process optimization, and predictive modeling for scalable implementation. By fostering interdisciplinary collaboration across microfluidics, fluid mechanics, geophysics, materials science, and subsurface engineering, we hope to accelerate innovation and advance sustainable energy solutions.
format Preprint
id arxiv_https___arxiv_org_abs_2503_04180
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Advancing sustainable energy solutions with microfluidic porous media
Lei, Wenhai
Yang, Yuankai
Yang, Shuo
Zhang, Ge
Poonoosamy, Jenna
Juel, Anne
Meheust, Yves
Bagheria, Shervin
Wang, Moran
Fluid Dynamics
The transition to a sustainable, low-carbon energy future requires transformative advancements in energy and environmental technologies. Carbon capture and sequestration, underground hydrogen storage, and nuclear waste geological disposal will be central aspects of a sustainable energy future, both for mitigating CO2 emissions and providing green energy. A comprehensive understanding of multiphase flow through porous media, along with reactive transport and microbial activities, is essential for assessing the feasibility and managing the risks of these technologies. Microfluidic porous media platforms have emerged as powerful tools for the direct visualization of multiphase reactive flow in porous media and eventually optimizing these multiple physicochemical and biological processes. This review highlights critical scientific challenges associated with these sustainable energy solutions and summarizes the state-of-the-art microfluidic techniques for studying the interplay between multiphase flow, reactive transport, and biological effects in porous media. We provide a comprehensive overview of how these microfluidic approaches enhance the understanding of fundamental pore-scale dynamics and bridge the gap between pore-scale events and large-scale processes. This review is expected to promote both experimental and theoretical understanding of multiphase reactive flow in porous media, thereby informing material design, process optimization, and predictive modeling for scalable implementation. By fostering interdisciplinary collaboration across microfluidics, fluid mechanics, geophysics, materials science, and subsurface engineering, we hope to accelerate innovation and advance sustainable energy solutions.
title Advancing sustainable energy solutions with microfluidic porous media
topic Fluid Dynamics
url https://arxiv.org/abs/2503.04180