Concept analysis of an indirect particle-based redox process for solar-driven H2O/CO2 splitting

Solar Energy

Volumn 113, Issue , 2015, Pages 158-170

  Brendelberger, Stefan ^a   Sattler, Christian ^a  

^a GERMAN AEROSPACE CENTER DLR   (Germany)

Author keywords

Heat recovery; Heat transfer particle; Redox cycle; Solar fuel

Indexed keywords

BOUNDARY CONDITIONS; DESIGN; EFFICIENCY; MASS TRANSFER; METAL DRAWING; REDOX REACTIONS; WASTE HEAT; WASTE HEAT UTILIZATION;

DESIGN AND OPERATIONS; HEAT AND MASS TRANSFER; INCREASED FLEXIBILITY; OXYGEN PARTIAL PRESSURE; REDOX CYCLES; SOLAR FUELS; TECHNICAL LIMITATIONS; THERMODYNAMIC STUDIES;

HEAT TRANSFER;

BOUNDARY CONDITION; CHEMICAL REACTION; CONCEPTUAL FRAMEWORK; DESIGN; HEAT TRANSFER; MODEL TEST; OPERATIONS TECHNOLOGY; REDOX CONDITIONS; SOLAR POWER; THERMODYNAMICS;

EID: 84921493780     PISSN: 0038092X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.solener.2014.12.035     Document Type: Article

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