Articles & Issues
- Language
- English
- Conflict of Interest
- In relation to this article, we declare that there is no conflict of interest.
- Publication history
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Received December 27, 2024
Revised March 28, 2025
Accepted April 16, 2025
Available online August 25, 2025
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This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/bync/3.0) which permits
unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.
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3D Graphene‑Coupled Aerogel Nanoarchitectures: Emerging Paradigm Toward Sustainable Applications in Fuel Cell
https://doi.org/10.1007/s11814-025-00470-9
Abstract
electrical conductivity, making it highly attractive for a wide range of applications, including energy storage, electronics,
and environmental remediation. Over the past two decades, advancements in the synthesis and functionalization of GA have
led to significant innovations in fuel cell technology, particularly in enhancing catalytic activity, mass transport, and structural
stability. The three-dimensional (3D) network morphology of graphene-based aerogels provides a large surface area,
interconnected porous structure, and tunable properties, which are critical for optimizing fuel cell performance. This review
provides a comprehensive analysis of GA applications in fuel cell systems, focusing on its role in key components such as
the anode, cathode, catalyst support, and membrane. By leveraging its unique properties, GA has demonstrated remarkable
potential in improving fuel cell efficiency, reducing costs, and enhancing sustainability. For instance, GA-based catalysts
have shown comparable or superior performance to conventional platinum-based catalysts (Pt/C), while significantly reducing
the reliance on expensive and scarce precious metals. Beyond its technical advantages, the adoption of GA in fuel cell
technology aligns with global sustainability efforts, particularly with the United Nations Sustainable Development Goals
(SDGs) 7 (Affordable and Clean Energy) and 13 (Climate Action). By enabling cleaner energy conversion and reducing
greenhouse gas emissions, GA contributes to the transition toward a low-carbon economy and mitigating climate change
impacts. This study also highlights the challenges in scaling up GA production, ensuring long-term durability, and achieving
cost-effectiveness for commercial applications. Furthermore, it explores future opportunities for optimizing GA-based fuel
cells through advanced synthesis techniques, novel functionalization strategies, and integration with other nanomaterials. By
addressing these challenges and leveraging its unique properties, GA has the potential to revolutionize fuel cell technology
and pave the way for next-generation sustainable energy solutions.
