中文
Earlier issues
Announcement
More
Progress in Chemistry 2010, Vol. 22 Issue (10): 1911-1920 Previous Articles   Next Articles

• Review •

Cobalt-based Catalyst for Selective Synthesis of Clean Liquid Fuel via Fischer-Tropsch Synthesis

Shao Yan  Yao Nan  Lu Chunshan   Lv Deyi   Liu Huazhang   Li Xiaonian**   

  1. (Institute of Industrial Catalysis, College of Chemical Engineering and Materials Science, State Key Laboratory Breeding Base of Green Chemistry-Synthesis Technology, Zhejiang University of Technology, Hangzhou, 310032, China)
  • Received: Revised: Online: Published:
  • Contact: Shao Yan E-mail:yanzi.shao@yahoo.com.cn
PDF ( 1447 ) Cited
Export

EndNote

Ris

BibTeX

The hydrocarbon products distribution of traditional Fischer-Tropsch synthesis (FTS) is controlled by Anderson-Schulz-Flory (ASF) kinetics. This leads to extensive carbon number distribution and nonselective products. How to break Anderson-Schulz-Flory kinetics is one of the front and hot topics in the research field of selective synthesis hydrocarbon via FTS. In this paper, we review the recent progress of the above area by discussing the relationship between the cobalt-based catalyst’s active sites and pore structure and product distribution.

Contents
1 Introduction
2 Controlling the hydrocarbon products distribution of F-T Synthesis by designing the catalyst’s active sites
2.1 Physical mixed bi-functional catalyst
2.2 Zeolite loaded bi-functional catalyst
2.3 Bi-functional catalyst with core-shell structure
3 Controlling the hydrocarbon products distribution of F-T Synthesis by changing supports’ pore structure
4 Conclusions and outlook

Key words: Fischer-Tropsch synthesis, Hydrocarbon product distribution, Catalytic active sites, Acidic support, Cobalt-based catalyst

[1 ] Khodakov A Y,Chu W,Fongarland P. Chem. Rev. ,2007,
107: 1692—1744
[2 ] Anderson R B. The Fischer-Tropsch Synthesis. Orlando:
Academic Press Inc. ,1984
[3 ] Schulz H. Appl. Catal. A: General,1999,186: 3—12
[4 ] Batholomew C H. AIChE Spring Meeting,New Orleans,LA,
2003,paper 83b
[5 ] Gloria H S,Duncan S. UK0199475,1989
[6 ] Patzlaff J,Liu Y,Graffmann C,Gaube J. Appl. Catal. ,1999,
186: 109—119
[7 ] Friedel R A,Anderson R B. J. Am. Chem. Soc. ,1950,72:
1212—1215
[8 ] Flory P J. J. Am. Chem. Soc. ,1936,58: 1877—1885
[9 ] Dry M E. The Fischer-Tropsch Synthesis in Catalysis: Sci. and
Tech. ,Ⅰ ( eds. Anderson J R,Boudart M) . Springer-Verlag,1981
[10] Dupain X,Krul R A,Makkee M,Moulijn J A. Catal. Today,
2005,106: 288—292
[11] Borodko Y,Somorjai G A. Appl. Catal. A: Gen. ,1999,186:
355—362
[12] The Sasol Story: A half-century of technological innovation.
[2009-09-20]. http: / / sasol. investoreports. com / sasol _mm_
2006 / index. php
[13] 南非SASOL 公司网. [2009-09-20]http: / /www. Sasol. Com
[14] Bromfield T C,Vosloo A C. Macromol. Symp. ,2003,193:
29—34
[15] Hoek A,Kersten L B J M. Stud. Surf. Sci. ,Catal. ,2004,
147: 25—30
[16] Raoa V U S,Stiegela G J. Fuel Process Technology,1992,30:
83—107
[17] Espinoza R L,Steynberg A P,Jager B,Vosloo A C. Applied
Catalysis A: General,1999,186: 13—26
[18] Khodakov A Y,Chu W,Fongarland P. Chem. Rev. ,2007,
107: 1692—1744
[19] Song C S. Catal. Today,2006,115: 2—32
[20] DOE /NETL, Carbon Sequestration. Technology Roadmap and
Program Plan 2005. US Department of Energy,National Energy
Technology Laboratory,May 2005. [2009-09-20]. http: / / fossil.
energy. gov / sequestration / publications / programplans /2005 /
sequestrationroadmap2005. pdf
[21] Rajagopalan K,Young G W. Fluid Catalytic Cracking. NY:
American Chemical Society,1988. 34—48
[22] Schulz H,Niederberger H L,Kneip M,Weil F. Stud. Surf.
Sci. Catal. ,1991,61: 313—324
[23] Nam I,Chuo K M,Seo J G,Hwang S,Jun K W,Song I K.
Catal. Lett. ,2009,130: 192—197
[24] Ngamcharussrivichai C,Liu X,Li X,Vitidsant T,Fujimoto K.
Fuel,2007,86: 50—59
[25] Li X H,Asami K,Luo M F,Michiki K,Tsubaki N,Fujimoto
K. Catalysis Today,2003,84: 59—65
[26] Jothimurugesan K, Gangwal S K. Ind. Eng. Chem. Res. ,
1998,37: 1181—1188
[27] 李宇萍( Li Y P) ,王铁军(Wang T J) ,吴创之(Wu C Z) ,吕
永兴( Lv Y X) ,李海滨( Li H B) . 石油化工( Petro Chemical
Technology) ,2008,37(5) : 445—449
[28] Li X H,Yang J N,Liu Z W,Asami K,Fujimoto K. Journal of
the Japan Petroleum Institute,2006,49: 86—90
[29] Thomson R T,Wolf E E. Applied Catalysis,1988,41: 65—80
[30] 刘雪暖( Liu X N) ,邹钢( Zou G) ,李玉秋( Li Y Q) . 石油化
工高等学校学报( Journal of Petrochemical Unirersity) ,2000,
13(3) : 9—12
[31] Murata K,Okabe K,Takahara I,Inaba H. JP 2010001241,
2010
[32] Yoneyama Y,Sun X Y,Zhao T S,Wang T J,Iwai T,Ozaki K,
Tsubaki N. Catalysis Today,2010,149: 105—110
[33] Liu Z W,Li X H,Fujimoto K. Energy & Fuels,2005,19:
1790—1794
[34] Liu Z W,Li X H,Fujimoto K. Fuel Processing Technology,
2007,88: 165—170
[35] Liu Z W,Asami K,Fujimoto K. Catalysis Communications,
2005,6: 503—506
[36] Li X H,Liu X,Liu Z W,Asami K,Fujimoto K. Catalysis
Today,2005,106: 154—160
[37] Liu Z W,Li X H,Asami K,Fujimoto K. Appl. Catal. A:
General,2006,300: 162—169
[38] Liu Z W,Li X H,Asami K,Fujimoto K. Catalysis Today,
2005,104: 41—47
[39] Li X H,Feng X L,Ge Q,Fujimoto K. Fuel,2008,87: 534—
538
[40] Yoneyama Y,San X G,Iwai T,Tsubaki N. Energy & Fuels,
2008,22: 2873—2876
[41] Guczi L, Kiricsi I. Appl. Catal. A: General,1999,186:
375—394
[42] Jong S J,Cheng S. Appl. Catal. A: General,1995,126: 51—
66
[43] Rossin J A,Davis M E. Division of Fuel Chemistry,1986,31:
71—74
[44] Altwasser S, Glser R, Weitkamp J. Microporous and
Mesoporous Materials,2007,104: 281—288
[45] Shamsi A,Rao V U S,Gormley R J,Obermyer R T,Schehl R
R,Stencel J M. Ind. Eng. Chem. Prod. Res. Dev. ,1984,
23: 513—519
[46] Sun S,Fujimoto K,Yoneyama Y,Tsubaki N. Fuel,2002,81:
1583—1591
[47] Wang W J,Lin H Y,Chen Y W. Journal of Porous Materials,
2005,12: 5—12
[48] Bessell S. Appl. Catal. A: General,1993,96: 253—268
[49] Calleja G,de Lucas A,van Grieken R. Appl. Catal. ,1991,
68: 11—29
[50] Li Y P,Wang T J,Wu C Z,Qin X X,Tsubaki N. Catalysis
Communication,2009,10: 1868—1874
[51] Tang Q H,Wang Y,Zhang Q H,Wan H L. Catal. Commun. ,
2003,4: 253—258
[52] Yang G H,Tan Y S,Han Y Z,Qiu J S,Tsubaki N. Catalysis
Communication,2008,9: 2520—2524
[53] Yang G H,He J J,Yoneyama Y,Tan Y S,Han Y Z,Tsubaki
N. Res. Chem. Intermed. ,2008,34: 771—779
[54] He J,Yoneyama Y,Xu B,Nishiyama N,Tsubaki N. Langmuir,
2005,21: 1699—1702
[55] He J J,Liu Z L,Yoneyama Y,Nishiyama N, Tsubaki N.
Chem. Eur. J. ,2006,12: 8296—8304
[56] Li X G,He J J,Meng M,Yoneyama Y,Tsubaki N. Journal of
Catalysis,2009,265: 26—34
[57] Yang G H,He J J,Zhang Y,Yoneyama Y,Tan Y S,Han Y Z,
Vitidsant T,Tsubaki N. Energy & Fuel,2008,22: 1463—1468
[58] Iglesia E. Appl. Catal. A: Gen. ,1997,161: 59—78
[59] Soled S L,Iglesia E,Fiato R A,Baumgartner J E,Vroman H,
Miseo S. Topics in Catalysis,2003,26: 101—109
[60] Martinez A,Rollan J,Arribas M A,Cerqueira H S,Costa A F,Falabella E. J. Catal. ,2007,249: 162—173
[61] Pour A N,Shahri S M K,Zamani Y,Irani M,Tehrani S.
Journal of Natural Gas Chemistry,2008,17: 242—248
[62] Liu Y C,Fang K G,Chen J G,Sun Y H. Green Chem. ,2007,
9: 611—615
[63] Van der Laan G P,Beenackers A A C M. Catal. Rev. Sci.
Eng. ,1999,41: 255—264
[64] Li Y P,Wang T J,Wu C Z,Lv Y X,Tsubaki N. Energy &
Fuels,2008,22: 1897—1901
[65] 李宇萍( Li Y P) ,王铁军(Wang T J) ,吴创之(Wu C Z) ,李
新军( Li X J) ,吕永兴( Lv Y X) . 现代化工(Modern Chemical
Industy) ,2008,28(2) : 43—46
[66] Zhao D Y,Feng J L,Huo Q S,Melosh N,Fredrickson G H,
Chmelka B F,Stucky G D. Science,1998,279: 548—552
[67] Khodakov A Y,Bechara R,Griboval-Constant A. Appl. Catal.
A,2003,254: 273—288
[68] Cai Q,Li J. Catal. Commun. ,2008,9: 2003—2006
[69] Xiong H F,Zhang Y H,Liew K Y,Li J L. Journal of Molecular
Catalysis A: Chemical,2008,295: 68—76
[70] Hong J P,Chernavskii P A,Khodakov A Y,Chu W. Catalysis
Today,2009,140: 135—141
[71] Xiong H F,Zhang Y H,Liew K Y,Li J L. Fule Process
Technol. ,2009,90: 237—246
[72] Martínez A,Prieto G. Top. Catal. ,2009,52: 75—90
[73] Sun Y,Jia L,Li D,Mu S. CN101224425,2008
[74] Gonzalo P,Agustin M,Raul M,Maria A A. Applied Catalysis
A: General,2009,367: 146—156
[75] 银董红(Yin D H) ,李文怀( Li W H) ,钟炳( Zhong B) ,彭少
逸( Peng S Y ) . 催化学报( Chinese Journal of Catalysis ) ,
2000,21(3) : 221—224
[76] 银董红(Yin D H) ,李文怀( Li W H) ,钟炳( Zhong B) ,彭少
逸( Peng S Y ) . 催化学报( Chinese Journal of Catalysis ) ,
2002,23(2) : 118—120
[77] González O,Pérez H,Navarro P,Almeida L C,Pacheco J G,
Montes M. Catalysis Today,2009,148: 140—147
[78] Khodakov A Y,Griboval-Constant A,Bechara R,Zholobenko V
L. Journal of Catalysis,2002,206: 230—241
[79] Christensen C H,Johannsen K,Trnqvist E,Schmidt I,Topse
H,Christensen C H. Catalysis Today,2007,128: 117—122
[80] 杨文书(Yang W S) ,房鼎业( Fang D Y) ,相宏伟( Xiang H
W) . 催化学报( Chinese Journal of Catalysis) ,2005,26 ( 4 ) :
329—334
[81] Lira E,Lopez C M,Oropeza F. J. Mol. Catal. A: Chem. ,
2008,281: 146—153
[82] 杨文书(Yang W S) ,高海燕( Gao H Y) ,相宏伟( Xiang H
W) ,银董红(Yin D H) ,杨勇(Yang Y) ,徐元源( Xu Y Y) ,
钟炳( Zhong B) ,李永旺( Li Y W) . 高等学校化学学报
( Chemical Journal of Chinese Universities ) ,2002,23 ( 9 ) :
1748—1752
[1] Yang Linyan, Guo Yupeng, Li Zhengjia, Cen Jie, Yao Nan, Li Xiaonian. Modulation of Surface and Interface Properties of Cobalt-Based Fischer-Tropsch Synthesis Catalyst [J]. Progress in Chemistry, 2022, 34(10): 2254-2266.
[2] Shi Yumei Yao Nan Lu Chunshan Fan Yangbo Liu Huazhang Li Xiaonian*. Highly Dispersed Supported Co Catalysts for Fischer-Tropsch Synthesis [J]. Progress in Chemistry, 2009, 21(10): 2044-2052.
[3] . Effects of Noble Metal Promoter on Supported Cobalt-Based Fischer-Tropsch Catalysts [J]. Progress in Chemistry, 2009, 21(04): 622-628.
[4] Wei Zhou*,Kegong Fang,Jiangang ,Chen,Yuhan Sun*. Effects of Water on Cobalt-Based Fischer-Tropsch Synthesis [J]. Progress in Chemistry, 2006, 18(01): 45-50.
[5] Wu Baoshan,Tian Lei,Bai Liang,Zhang Zhixin,Xiang Hongwei**,Li Yongwang. R&D of Precipitated Iron Catalysts in Fischer-Tropsch Synthesis [J]. Progress in Chemistry, 2004, 16(02): 256-.