Author(s):
Kunwar Pala, Abdul Rafey, and Kamal Kishore Pant,

Abstract:
The thermochemical conversion of agro-waste presents a sustainable pathway for green hydrogen production, addressing both energy and environmental challenges. Agricultural residues, such as crop straw, husks, and forestry waste, are abundant and rich in carbon content, making them viable feedstocks for hydrogen generation. Key thermochemical processes include pyrolysis, gasification, and hydrothermal liquefaction, each offering unique advantages in converting biomass into hydrogen-rich syngas. Gasification, in particular, operates at high temperatures with controlled oxygen or steam to enhance hydrogen yield while minimizing tar formation. Advanced catalysts and sorbents further improve hydrogen selectivity and carbon capture efficiency. Process optimization, including temperature control, catalyst selection, and reactor design, is crucial in maximizing hydrogen output and minimizing impurities such as CO and CH4. Integrating carbon capture and storage (CCS) technologies enhances the sustainability of hydrogen production by reducing greenhouse gas emissions. Additionally, hybrid approaches combining thermochemical methods with biological or electrochemical processes offer the potential for improved efficiency and scalability. Despite its promise, challenges remain, including feedstock variability, high capital costs, and the need for technological advancements in process efficiency. Research efforts focus on developing cost-effective catalysts, optimizing reaction conditions, and utilizing artificial intelligence for process control. Policy support, investment in bio-refinery infrastructure, and life cycle assessment studies will be critical for commercializing this approach. Thermochemical conversion of agro-waste thus emerges as a promising strategy for producing green hydrogen, contributing to the global transition toward sustainable and carbon-neutral energy systems.

Pages: 497-509

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