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Waste‑to‑hydrogen technologies: Advances in catalytic, thermochemical, and biochemical conversion pathways for a circular hydrogen economy

Ganesan Subbiah, Ritesh Pratap Singh, Chilukuri Sulakshana, Sikata Samantaray, Shivendu Saxena, Somashekar DP, Prem Nath Suman, Kamakshi Priya K

2025Results in Engineering10 citationsDOIOpen Access PDF

Abstract

The evolution towards a circular hydrogen economy requires the deployment of sophisticated technologies capable of transforming various waste streams into high-purity hydrogen while minimizing environmental impacts. This review presents a comprehensive evaluation of recent advancements in catalytic, thermochemical, and biochemical methodologies, highlighting their operational efficacy, techno-economic viability, and environmental sustainability. Catalytic methodologies, including nanostructured, photocatalytic, and electrocatalytic systems, have achieved hydrogen production rates of 100–250 mL H₂ g⁻¹ h⁻¹ with Faradaic efficiencies of 80–90 %. However, obstacles such as catalyst deactivation and scalability issues persist. Thermochemical methodologies, encompassing pyrolysis, gasification, and plasma-assisted reforming, generate syngas comprising 20–55 vol% H₂ with energy demands of 0.6–0.8 mol H₂ kWh⁻¹; however, they necessitate trade-offs between capital intensity and operational expenses. Biochemical techniques, such as dark fermentation (DF), photofermentation (PF), and microbial electrolysis cells (MECs), exhibit yields of 2–6 mol H₂ mol⁻¹ substrate under moderate conditions, with potential for co-product valorization, yet constrained by sluggish kinetics and pretreatment requirements. Comparative life-cycle assessment (LCA) and techno-economic analysis (TEA) suggest that hybrid systems amalgamating thermochemical and biochemical pathways can achieve costs as low as 1.8–2.5 USD kg⁻¹ H₂ and lifecycle emissions below 2 kg CO₂ kg⁻¹ H₂, thereby surpassing single-process configurations.

Topics & Concepts

Hydrogen economyBiochemical engineeringHydrogen productionCircular economyMicrobial electrolysis cellHydrogenChemistryDark fermentationElectrolysis of waterCatalysisProcess engineeringEnvironmental scienceSoftware deploymentEnergy carrierElectrolysisSubstrate (aquarium)Waste managementNanotechnologyFermentationHydrogen technologiesFuel cellsHydrogen fuelBiorefineryProduction (economics)Computer scienceHybrid Renewable Energy SystemsCatalysts for Methane ReformingCatalytic Processes in Materials Science