Catalytic Performance and Kinetic Models on Zirconium Phosphate Modified Ru/Co/SiO2 Fischer-Tropsch Catalyst
- Authors
- Lee, B[Lee, BalSang]; Jang, IH[Jang, In Hyeok]; Bae, JW[Bae, Jong Wook]; Um, SH[Um, Soong Ho]; Yoo, PJ[Yoo, Pil J.]; Park, MJ[Park, Myung-June]; Lee, YC[Lee, Yong Chul]; Jun, KW[Jun, Ki-Won]
- Issue Date
- Sep-2012
- Publisher
- SPRINGER/PLENUM PUBLISHERS
- Keywords
- Fischer-Tropsch synthesis; Cobalt; Zirconium phosp
- Citation
- CATALYSIS SURVEYS FROM ASIA, v.16, no.3, pp.121 - 137
- Indexed
- SCIE
SCOPUS
- Journal Title
- CATALYSIS SURVEYS FROM ASIA
- Volume
- 16
- Number
- 3
- Start Page
- 121
- End Page
- 137
- URI
- https://scholarworks.bwise.kr/skku/handle/2021.sw.skku/64461
- DOI
- 10.1007/s10563-012-9139-y
- ISSN
- 1571-1013
- Abstract
- The present paper represents the promising ways to improve catalytic performance by introducing zirconium phosphate (ZP) on Ru/Co/SiO2 catalysts and the related kinetic models using the optimized Fischer-Tropsch synthesis (FTS) catalyst. A lot of works has been reported using cobalt-based catalyst for FTS reaction, and many authors have continuously tried to find out highly efficient FTS catalyst by modifying support as well as by introducing promoters. Silica is one of the excellent candidates as catalytic supports, and the present works intensively represents how to modify SiO2 support for a high catalytic performance by using ZP species. The effect of ZP-modification of SiO2 support with respect to cobalt aggregation and catalytic deactivation was mainly investigated for FTS reaction. The surface modification at P/(Zr + P) molar ratio between 0.029 and 0.134, enhanced the spatial confinement effect of cobalt clusters, and resulted in high catalytic stability with the help of well-dispersed ZP particle formation. The enhanced catalytic performance, in terms of CO conversion, C-5+ selectivity and catalytic stability, is mainly attributed to the suppressed aggregation, a homogeneous distribution of cobalt clusters with a proper size and a low mobility of cobalt clusters at an optimum molar ratio of P/(Zr + P) because of the formation of thermally stable ZP particles. The kinetic parameters and rate equations on the optimized catalyst are also derived in terms of CO conversion and product distribution.
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- Appears in
Collections - Engineering > Chemical Engineering > 1. Journal Articles
- Engineering > School of Chemical Engineering > 1. Journal Articles
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