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Solar-driven chemical looping combustion: A pathway to low-impact carbon emission and sustainable hydrogen generation for a decarbonized energy sector

Mohammad Saeedan, Ehsan Houshfar

2025Fuel Processing Technology14 citationsDOIOpen Access PDF

Abstract

This study investigates a solar-driven chemical looping combustion (CLC) system for sustainable hydrogen production. A high-temperature CLC model was developed and optimized through sensitivity analysis, revealing that increasing iron steam reactor pressure (optimal: 40 bar) and steam flow rate enhances hydrogen production by up to 28 %, while higher solar‑iron reactor pressure reduces output by 19 % due to reaction equilibrium constraints. The solar-CLC hybrid system demonstrated superior performance, with the high-temperature model producing 10,500 kmol/h of hydrogen—96 % more than the low-temperature model (5348 kmol/h) and 135 % more than non-solar CLC. Exergy analysis confirmed the iron-steam reactor as the most efficient component (90 % efficiency), whereas the iron-fuel reactor exhibited the highest losses (50 % efficiency). Shiraz as the most favorable location, required 32 % fewer mirrors than Ahvaz (the least suitable city) due to its higher solar irradiance (123.2 vs. 88.6 kWh/m 2 DNI). Chabahar achieved the highest hydrogen yield (11,803 kmol/day) owing to extended daylight hours. Phase-change material storage analysis showed Chabahar needed 40 % fewer storage modules than Shiraz. Solar-CLC integration outperforms traditional CLC in both efficiency and emissions reduction, with the high-temperature model being optimal for high-irradiance regions. The findings provide actionable insights for deploying renewable-powered hydrogen systems in decarbonizing the energy sector.

Topics & Concepts

HydrogenCarbon fibersChemical looping combustionCombustionSustainable energyGreenhouse gasChemistryEnvironmental scienceMaterials scienceRenewable energyPhysical chemistryEngineeringComposite numberOrganic chemistryBiologyElectrical engineeringComposite materialEcologyChemical Looping and Thermochemical ProcessesOil, Gas, and Environmental IssuesThermodynamic and Exergetic Analyses of Power and Cooling Systems
Solar-driven chemical looping combustion: A pathway to low-impact carbon emission and sustainable hydrogen generation for a decarbonized energy sector | Litcius