甲酸为氢源的甘油催化选择氢解

催化学报 , 2013, 34(11): 2066-2074. doi: 10.1016/S1872-2067(12)60656-1

甲酸为氢源的甘油催化选择氢解

袁静 ^1, , 李舒爽 ^2, , 于磊 ^3, , 刘永梅 ^4, , 曹勇 ^5,

1.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

2.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

3.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

4.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

5.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

基金项目: 国家自然科学基金(21273044).This work was supported by the National Natural Science Foundation of China (21273044)

关键词：铜 , 二氧化锆 , 氢解 , 甘油 , 甲酸

Efficient catalytic hydrogenolysis of glycerol using formic acid as hydrogen source

Jing Yuan ^1, , Shushuang Li ^2, , Lei Yu ^3, , Yongmei Liu ^4, , Yong Cao ^5,

1.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

2.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

3.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

4.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

5.复旦大学化学系,上海市分子催化和功能材料重点实验室,上海200433

Keywords： Copper , Zirconium dioxide , Hydrogenolysis , Glycerol , Formic acid

以甲酸作为氢源,采用铜基复合金属氧化物催化剂,催化氢解甘油制备1,2-丙二醇,其中液相甲酸的高选择性分解是实现甘油氢解的必要和关键步骤.活性测试表明,高分散的铜和ZrO2载体间的协同作用对甲酸分解和甘油到1,2-丙二醇的转化至关重要,20％Cu/ZrO2催化剂的活性最佳.由于避免使用相对昂贵的化石燃料氢,因而该催化体系在生物质的高值利用方面具有潜在的应用前景.

参考文献

[1]	Huber G W;lborra S;Corma A .[J].Chemical Reviews,2006,106:4044.
[2]	Corma A;Iborra S;Velty A .[J].Chemical Reviews,2007,107:2411.
[3]	Martin A;Armbruster U;Gandarias l;Arias P L .[J].European Journal of Lipid Science and Technology,2013,115:9.
[4]	Brandner A;Lehnert K;Bienholz A;Lucas M Claus P .[J].Topics in Catalysis,2009,52:278.
[5]	Nakagawa Y;Tomishige K .[J].Catalysis Science & Technology,2011,1:179.
[6]	Gandarias, I.;Arias, P.L.;Requies, J.;El Doukkali, M.;Güemez, M.B. .Liquid-phase glycerol hydrogenolysis to 1,2-propanediol under nitrogen pressure using 2-propanol as hydrogen source[J].Journal of Catalysis,2011(1):237-247.
[7]	Bolado S;Trevi(n)o R E;García-Cubero M T;González-Benito G .[J].Catalysis Communications,2010,12:122.
[8]	Yuan Z L;Wu P;Gao J;Lu X Y Hou Z Y Zheng X M .[J].Catalysis Letters,2009,130:261.
[9]	Qin L Z;Song M J;Chen C L .[J].Green Chemistry,2010,12:1466.
[10]	Oh J;Dash S;Lee H .[J].Green Chemistry,2011,13:2004.
[11]	Miyazawa T;Kusunoki Y;Kunimori K;Tomishige K .Glycerol conversion in the aqueous solution under hydrogen over Ru/C plus an ion-exchange resin and its reaction mechanism[J].Journal of Catalysis,2006(2):213-221.
[12]	Maris E P;Davis R J .[J].Journal of Catalysis,2007,249:328.
[13]	Meher L C;Gopinath R;Naik S N;Dalai A K .[J].Industrial and Engineering Chemistry Research,2009,48:1840.
[14]	Furikado I;Miyazawa T;Koso S;Shimao A Kunimori K Tomishige K .[J].Green Chemistry,2007,9:582.
[15]	Jones S;Qu J;Tedsree K;Gong X Q Tsang S C E .[J].Angewandte Chemie International Edition,2012,51:11275.
[16]	Yi N;Saltsburg H;Flytzani-Stephanopoulos M .[J].ChemSusChem,2013,6:816.
[17]	Gandariasa I;Requies J;Arias P L;Armbruster U Martin A .[J].Journal of Catalysis,2012,290:79.
[18]	Du X L;He L;Zhao S;Liu Y M Cao Y He H Y Fan K N .[J].Angewandte Chemie International Edition,2011,50:7815.
[19]	Tedsree, K.;Li, T.;Jones, S.;Chan, C.W.A.;Yu, K.M.K.;Bagot, P.A.J.;Marquis, E.A.;Smith, G.D.W.;Tsang, S.C.E. .Hydrogen production from formic acid decomposition at room temperature using a Ag-Pd core-shell nanocatalyst[J].Nature nanotechnology,2011(5):302-307.
[20]	Ojeda M;Iglesia E .[J].Angewandte Chemie International Edition,2009,48:4800.
[21]	Solymosi, F.;Koós, á.;Liliom, N.;Ugrai, I. .Production of CO-free H_2 from formic acid. A comparative study of the catalytic behavior of Pt metals on a carbon support[J].Journal of Catalysis,2011(1):213-219.
[22]	Gazsi A;Bansagi T;Solymosi F .[J].The Journal of Physical Chemistry C,2011,115:15459.
[23]	Huang Z W;Cui F;Kang H X;Chen J Zhang X Z Xia C G .[J].Chemistry of Materials,2008,20:5090.
[24]	Liang C H;Ma Z Q;Ding L;Qiu J S .[J].Catalysis Letters,2009,130:169.
[25]	Wang L C;Liu Q;Chen M;Liu Y M Cao Y He H Y Fan K N .[J].The Journal of Physical Chemistry C,2007,11:16549.
[26]	Zhang, XR;Wang, LC;Yao, CZ;Cao, Y;Dai, WL;He, HY;Fan, KN .A highly efficient Cu/ZnO/Al2O3 catalyst via gel-coprecipitation of oxalate precursors for low-temperature steam reforming of methanol[J].Catalysis Letters,2005(3/4):183-190.
[27]	Yao CZ;Wang LC;Liu YM;Wu GS;Cao Y;Dai WL;He HY;Fan KN .Effect of preparation method on the hydrogen production from methanol steam reforming over binary Cu/ZrO2 catalysts[J].Applied Catalysis, A. General: An International Journal Devoted to Catalytic Science and Its Applications,2006(2):151-158.
[28]	Bi, Q.-Y.;Du, X.-L.;Liu, Y.-M.;Cao, Y.;He, H.-Y.;Fan, K.-N. .Efficient subnanometric gold-catalyzed hydrogen generation via formic acid decomposition under ambient conditions[J].Journal of the American Chemical Society,2012(21):8926-8933.
[29]	Zhou XC;Huang YJ;Xing W;Liu CP;Liao JH;Lu TH .High-quality hydrogen from the catalyzed decomposition of formic acid by Pd-Au/C and Pd-Ag/C[J].Chemical communications,2008(30):3540-3542.
[30]	Huang Y J;Zhou X C;Yin M;Liu C P Xing W .[J].Chemistry of Materials,2010,22:5122.
[31]	Xia S X;Yuan Z L;Wang L N;Chen P Hou Z Y .[J].Applied Catalysis A:General,2011,403:173.
[32]	Xia S X;Nie R F;Lu X Y;Wang L N Chen P Hou Z Y .[J].Journal of Catalysis,2012,296:1.

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