Advancements in Biomass‐Derived Activated Carbon for Sustainable Hydrogen Storage: A Comprehensive Review

This review explores the potential of biomass-derived activated carbon (AC) as a pivotal solution for hydrogen storage challenges. Highlighting its eco-friendliness, cost-effectiveness, and superior adsorption qualities, the work navigates through the synthesis and characterization methodologies of AC. The emphasis on the advantages of biomass sources, coupled with a deep dive into hydrogen uptake and release capacities, sets the stage for future innovations in sustainable hydrogen storage.

Abstract

The increasing global energy demand, which is being driven by population growth and urbanization, necessitates the exploration of sustainable energy sources. While traditional energy generation predominantly relies on fossil fuels, it also contributes to alarming CO₂ emissions. Hydrogen has emerged as a promising alternative energy carrier with its zero-carbon emission profile. However, effective hydrogen storage remains a challenge. When exposed to hydrogen, conventional metallic vessels, once considered to be the primary hydrogen carriers, are prone to brittleness-induced cracking. This has spurred interest in alternative storage solutions, particularly porous materials like metal-organic frameworks and activated carbon (AC). Among these, biomass-derived AC stands out for its eco-friendly nature, cost-effectiveness, and optimal adsorption properties. This review offers a comprehensive overview of recent advancements in the synthesis, characterization, and hydrogen storage capabilities of AC. The unique benefits of biomass-derived sources are highlighted, as is the pivotal role of chemical and physical activation processes. Furthermore, we identify existing challenges and propose future research directions in AC-based hydrogen storage. This compilation aims to serve as a foundation for potential innovations in sustainable hydrogen storage solutions.

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