화학공학소재연구정보센터
로그인 로그아웃 연락처 사이트맵
Korean Chemical Engineering Research, Vol.55, No.2, 156-162, April, 2017
DOI10.9713/kcer.2017.55.2.156  Export Citation
Al-Ce 산화물에 담지된 CuO 촉매상에서 저온 CO산화반응
Low Temperature CO Oxidation over CuO Catalyst Supported on Al-Ce Oxide Support
박정현, 윤현기1, 신채호2, †
  • 한국화학연구원 탄소화자원연구소 온실가스자원화그룹, 34114 대전광역시 유성구 가정로 141
  • 1충북대학교 산학협력단, 28644 충청북도 청주시 서원구 충대로 1
  • 2충북대학교 화학공학과, 28644 충청북도 청주시 서원구 충대로 1
Jung-Hyun Park, Hyun Ki Yun1, and Chae-Ho Shin2, †
  • Greenhouse Gas Resources Research Group, Carbon Resource, Korea Research Institute of Chemical TechnologyInstitute, 141, Gajeong-ro, Yuseong-gu, Daejeon, 34114, Korea
  • 1Industry-University Cooperation Foundation, Chungbuk National University, 1, Chungdae-ro, Seowon-gu, Cheongju, Chungbuk, 28644, Korea
  • 2Department of Chemical Engineering, Chungbuk National University, 1, Chungdae-ro, Seowon-gu, Cheongju, Chungbuk, 28644, Korea
E-mail:
초록
CuO의 함량이 반응활성에 미치는 영향을 조사하기 위하여 CuO(x)/0.3Al-0.7Ce (x = 2~20 wt%) 촉매를 함침법으로 제조하고 저온 CO 산화반응을 수행하였다. CuO(10)/0.3Al-0.7Ce 촉매가 반응물 중 수분의 존재 유무에 관계없이 가장 우수한 반응활성을 나타내었다. 수분의 존재는 활성점에 CO와의 경쟁흡착으로 활성점이 감소하여 50% CO 전환율 온도인 T50%가 약 50 °C 고온으로 이동되어 관찰되었다. N2O-적정실험으로 구한 구리 표면적과 CO-펄스 실험으로 계산된 격자산소의 양은 CuO의 함량 증가에 따라 증가하였고, CuO(10)/0.3Al-0.7Ce 촉매에서 최대화되었다. 이러한 특성 분석결과는 사용된 촉매의 CO 산화반응에 대한 T50%의 경향과 잘 일치하였다. 위의 특성분석 결과로부터, CuO(x)/0.3Al-0.7Ce 촉매의 CO 산화반응에 대한 반응성은 구리 표면적과 격자산소의 양과 밀접하게 관련된다고 결론지을 수 있다.
CuO(x)/0.3Al-0.7Ce catalysts with different CuO loadings (x = 2~20 wt%) were prepared by impregnation method and investigated the effects of CuO loadings on the low temperature CO oxidation. Of the used catalysts, the CuO(10)/0.3Al-0.7Ce catalyst showed the highest catalytic performance in the absence or presence of water vapor. In the presence of water vapor, the catalytic performance was drastically decreased, with a temperature of 50% CO conversion (T50%) shifted to higher temperature by 50 °C compared to the those in dry conditions because of the competitive adsorption of water vapor on the active sites. The copper metal surface area calculated from N2O-titration analysis and the oxygen capacity from CO-pulse experiments were increased with the CuO loadings and showed a maximum at 10 wt%CuO/0.3Al-0.7Ce catalyst. These trends are in good agreement with the tendency of T50% of the catalysts. From these characteristic aspects, it could be deduced that the catalytic performance was closely related to the oxygen capacity and the copper metallic surface area.
Keywords:CuO/AlCe catalyst;CO oxidation;Copper surface area;Oxygen capacity
  1. Manzoli M, Di Monte R, Boccuzzi F, Coluccia S, Kaspar J, Appl. Catal. B: Environ., 61(3-4), 192 (2005)
  2. Hoflund GB, Gardner SD, Schryer DR, Upchurch BT, Kielin EJ, Appl. Catal. B: Environ., 6(2), 117 (1995)
  3. Botas JA, Gutierrez-Ortiz MA, Gonzalez-Marcos MP, Gonzalez-Marcos JA, Gonzalez-Velasco JR, Appl. Catal. B: Environ., 32(4), 243 (2001)
  4. Reddy BM, Rao KM, Catal. Commun., 10(9), 1350 (2009)
  5. Ruth K, Hayes M, Burch R, Tsubota S, Haruta M, Appl. Catal. B: Environ., 24(3-4), L133 (2000)
  6. Laguna OH, Centeno MA, Boutonnet M, Odriozola JA, Catal. Today, 278, 140 (2016)
  7. Park JH, Cho JH, Kang SE, Cho KH, Lee TW, Han HS, Shin CH, Korean J. Chem. Eng., 30(3), 598 (2013)
  8. Park JH, Cho KH, Kim YJ, Shin CH, Clean Technol., 17(2), 166 (2011)
  9. del Rio E, Hungria AB, Tinoco M, Manzorro R, Cauqui MA, Calvino JJ, Perez-Omil JA, Appl. Catal. B: Environ., 197, 86 (2016)
  10. Vedyagin AA, Volodin AM, Kenzhin RM, Stoyanovskii VO, Shubin YV, Plyusnin PE, Mishakov IV, Catal. Today (2016)
  11. Avgouropoulos G, Ioannides T, Appl. Catal. A: Gen., 244(1), 155 (2003)
  12. Sedmak G, Hocevar S, Levec J, J. Catal., 222(1), 87 (2004)
  13. Martinez-Arias A, Hungria AB, Munuera G, Gamarra D, Appl. Catal. B: Environ., 65(3-4), 207 (2006)
  14. Artizzu P, Garbowski E, Primet M, Brulle Y, Saint-Just J, Catal. Today, 47(1-4), 83 (1999)
  15. Sun K, Liu JY, Browning ND, Appl. Catal. B: Environ., 38(4), 271 (2002)
  16. Carniti P, Gervasini A, Modica VH, Ravasio N, Appl. Catal. B: Environ., 28(3-4), 175 (2000)
  17. Miyadera T, Appl. Catal. B: Environ., 16(2), 155 (1998)
  18. Pietrogiacomi D, Sannino D, Tuti S, Ciambelli P, Indovina V, Occhiuzzi M, Pepe F, Appl. Catal. B: Environ., 21(2), 141 (1999)
  19. Rao KN, Bharali P, Thrimurthulu G, Reddy BM, Catal. Commun., 11(10), 863 (2010)
  20. Sedmak G, Hocevar S, Levec J, J. Catal., 213(2), 135 (2003)
  21. Harrison PG, Ball IK, Azelee W, Daniell W, Goldfarb D, Chem. Mater., 12(12), 3715 (2000)
  22. Vidal H, Kaspar J, Pijolat M, Colon G, Bernal S, Cordon A, Perrichon V, Fally F, Appl. Catal. B: Environ., 30(1-2), 75 (2001)
  23. Li Y, Wang XX, Song CS, Catal. Today, 263, 22 (2016)
  24. Park JH, Shin CH, Korean Chem. Eng. Res.
  25. Zhao F, Gong M, Zhang G, Li J, J. Rare Earth, 33(6), 604 (2014)
  26. Evans JW, Wainwright MS, Bridgewater AJ, Young DJ, Appl. Catal., 7(1), 75 (1983)
  27. Hsin-Fu C, Abu SM, Wen-Su H, Wen-Hsiung L, J. Mol. Catal. A-Chem., 94(2), 233 (1994)
  28. Dow WP, Wang YP, Huang TJ, J. Catal., 160(2), 155 (1996)
  29. Ratnasamy P, Srinivas D, Satyanarayana CVV, Manikandan P, Kumaran RSS, Sachin M, Shetti VN, J. Catal., 221(2), 455 (2004)
  30. Flores JH, Peixoto DPB, Appel LG, de Avillez RR, da Silva MIP, Catal. Today, 172(1), 218 (2011)
  31. Bae JW, Kang SH, Lee YJ, Jun KW, Appl. Catal. B: Environ., 90(3-4), 426 (2009)
  32. Venugopal A, Palgunadi J, Deog JK, Joo OS, Shin CH, J. Mol. Catal. A-Chem., 302(1-2), 20 (2009)
  33. Liu W, Flytzanistephanopoulos M, J. Catal., 153(2), 304 (1995)
  34. Hasegawa Y, Fukumoto K, Ishima T, Yamamoto H, Sano M, Miyake T, Appl. Catal. B: Environ., 89(3-4), 420 (2009)
  35. Azzam KG, Babich IV, Seshan K, Lefferts L, J. Catal., 251(1), 153 (2007)
  36. Liu W, Sarofim AF, Flytzanistephanopoulos M, Appl. Catal. B: Environ., 4(2-3), 167 (1994)