High-temperature water gas shift reaction over Fe/Al/Cu oxide based catalysts using simulated waste-derived synthesis gas

Catalysis Letters

Volumn 143, Issue 5, 2013, Pages 438-444

  Jeong, Dae Woon ^a   Subramanian, Vijayanand ^a   Shim, Jae Oh ^a   Jang, Won Jun ^a   Seo, Yong Chil ^a   Roh, Hyun Seog ^a   Gu, Jae Hoi ^b   Lim, Yong Taek ^b  

^a Yonsei University Wonju   (South Korea)

^b Institute for Advanced Engineering (IAE)   (South Korea)

Author keywords

Fe Al Cu; Reducibility; Stability; Synergy effect; Waste derived synthesis gas; Water gas shift (WGS)

Indexed keywords

GAS HOURLY SPACE VELOCITIES; HIGH TEMPERATURE; HIGH-TEMPERATURE WATER; REDUCIBILITY; SYNERGY EFFECT; TEMPERATURE RANGE; WATER GAS SHIFT (WGS) REACTION; WATER-GAS SHIFTS;

CARBON DIOXIDE; CATALYST SELECTIVITY; CHEMICAL SHIFT; CONVERGENCE OF NUMERICAL METHODS; FISCHER-TROPSCH SYNTHESIS; HYDROGEN PRODUCTION; SYNTHESIS GAS;

WATER GAS SHIFT;

EID: 84880225761     PISSN: 1011372X     EISSN: 1572879X     Source Type: Journal    
DOI: 10.1007/s10562-013-0981-y     Document Type: Article

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