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1. Photocatalytic hydrogen generation over Eosin Y-Sensitized TS-1 ze.. [799]
2. Ion exchange synthesis of PAN/Ag3PO4 core-shell nanofibers with en.. [786]
3. TiO2 Nanotube Arrays Modified with Cr- Doped SrTiO3 Nanocubes for .. [760]
4. Low temperature CO oxidation over Pd-Ce catalysts supported on ZSM.. [724]
5. High performance rare earth oxides LnOx (Ln = La, Ce, Nd, Sm and D.. [723]
6. Morphology modulation of SrTiO3/TiO2 heterostructures for enhanced.. [718]
7. Investigation of the steam reforming of a series of model compound.. [621]
8. Fabrication of Ag3PO4–PAN composite nanofibers for photocatalytic.. [552]
9. Low temperature carbon monoxide catalytic oxidation at the Pd/Ce-Z.. [516]
10. Influence of promoter on the catalytic activity of high p.. [512]
11. Concave trisoctahedral Ag3PO4 microcrystals with high-index facets.. [511]
12. Visible-light-driven photoelectrochemical and photocatalytic perfo.. [498]
13. Hydrogen feed gas purification over bimetallic Cu–Pd catalysts –.. [490]
14. A new method to construct hierarchical ZSM-5 zeolites with excelle.. [476]
15. Butene catalytic cracking to ethylene and propylene on fluorinated.. [462]
16. Enhanced photocatalytic activity of Ag/Ag3PO4 coaxial hetero-nanow.. [457]
17. 低成本原料一步直接合成小晶粒ZSM-5分子筛(英文) [445]
18. Highly active Pd/Fe based catalyst prepared with polyol-red.. [437]
19. Enhanced Electron Transfer from the Excited Eosin Y to mpg-C3N4 fo.. [424]
20. Photocatalytic and photoelectric properties of cubic Ag3PO4 sub-mi.. [412]
21. Study of One Step Synthesis of Rare Earth Zeolite (Ln–ZSM-5) and .. [412]
22. Selective Growth of Metallic Ag Nanocrystals on Ag3PO4 Submicro-Cu.. [404]
23. Vertically aligned ZnO nanowire arrays tip-grafted with silver nan.. [401]
24. The roles of density-tunable surface oxygen vacancy over bouquet-l.. [394]
25. Promoted photoinduced charge separation and directional electron t.. [392]
26. Modification of TiO2 with sulfate and phosphate for enhanced eosin.. [385]
27. 不同染料共敏化TiO2可见光分解水产氢性能研究——染料结构相似性与双重.. [381]
28. Influence of the pore structure of CeO2 supports on the surface te.. [375]
29. Modification of ZnS1-x-0.5yOx(OH)(y)-ZnO photocatalyst with NiS fo.. [374]
30. Eosin Y-sensitized graphitic carbon nitride fabricated by heating .. [367]
31. Highly efficient hydrogen production from formaldehyde over Ag/gam.. [367]
32. Photocatalytic hydrogen evolution over Pt/Cd0.5Zn0.5S from saltwat.. [360]
33. Photosensitization of SiW11O398--modified TiO2 by Eosin Y for stab.. [359]
34. Two-dimensional dendritic Ag3PO4 nanostructures and their photocat.. [357]
35. New facile synthesis of one-dimensional Ag@TiO2 anatase core-shell.. [350]
36. Remarkable enhancement of photocatalytic hydrogen evolution over C.. [348]
37. Facile synthesis of tetrahedral Ag3PO4 submicro-crystals with enha.. [347]
38. Dye-cosensitized graphene/Pt photocatalyst for high efficient visi.. [346]
39. 杂多蓝的结构及其光化学研究进展 [345]
40. Fabrication and catalytic properties of Pd and Ce decorated carbon.. [343]
41. Effects of electrolyte NaCl on photocatalytic hydrogen evolution i.. [342]
42. 二氧化碳化学——现状及展望 [342]
43. Facile and Rapid Oxidation Fabrication of BiOCl Hierarchical Nanos.. [341]
44. High performance phosphorus-modified ZSM-5 zeolite for butene cata.. [339]
45. Photocatalytic hydrogen generation in the presence of glucose over.. [339]
46. Photo-directed growth of Au nanowires on ZnO arrays for enhancing .. [338]
47. Sites for High Efficient Photocatalytic Hydrogen Evolution on a Li.. [336]
48. Effect of epimerization of d-glucose on photocatalytic hydrogen ge.. [332]
49. Photosensitized reduction of water to hydrogen using novel Maya bl.. [331]
50. NaCl-assisted low temperature synthesis of layered Zn-In-S photoca.. [327]
51. 负载型氨基功能化离子液体吸附CO2性能差异研究 [325]
52. Butene catalytic cracking to ethylene and propylene on mesoporous .. [323]
53. 基于曙红Y氧化性猝灭的高活性和高稳定的可见光催化产氢催化剂 [323]
54. Fe3+偶联吨染料敏化TiO2可见光催化制氢活性 [321]
55. Highly efficient hydrogen production from alkaline aldehyde soluti.. [320]
56. TiO2 Photocatalytic Materials 2013 [319]
57. Acetic acid steam reforming to hydrogen over Co–Ce/Al2O3 and Co–.. [318]
58. 可见光还原水制氢ZnS-CdS/SiO2催化剂表面结构与性能的研究 [317]
59. Enhanced photocatalytic properties of biomimetic Ag/AgCl heterostr.. [315]
60. Photocatalytic hydrogen evolution under visible light irradiation .. [313]
61. Bio-oil steam reforming, partial oxidation or oxidative steam refo.. [311]
62. Direct conversion of Bi nanospheres into 3D flower-like BiOBr nano.. [308]
63. Morphology-dependent activity of silver nanostructures towards the.. [307]
64. Photocatalytic H2 evolution from NaCl saltwater over ZnS1-x-0.5yOx.. [306]
65. Eosin Y-sensitized nitrogen-doped TiO2 for efficient visible light.. [306]
66. Photocatalytic hydrogen generation in the presence of ethanolamine.. [304]
67. 表面活性剂修饰对MCM-41 负载离子液体吸附CO2影响的研究 [303]
68. Phosphate-assisted hydrothermal synthesis of hexagonal CdS for eff.. [301]
69. Electrocatalytic oxidation of carbon monoxide on platinum-modified.. [301]
70. Dye-Sensitized Reduced Graphene Oxide Photocatalysts for Highly Ef.. [297]
71. 高分子修饰Pt/ZnS-CdS/SiO2催化剂表面官能团调变与光催化制氢活性关系.. [297]
72. Deposition of Pd– Fe nanoparticles onto carbon spheres with contr.. [295]
73. Influence of particle size of ZSM-5 on the yield of propylene in f.. [293]
74. A highly effective Pt and H3PW12O40 modified zirconium oxide metal.. [293]
75. 半导体光催化剂制氢研究新进展 [289]
76. 回收低浓度金的方法 [287]
77. Photocatalytic hydrogen generation using glucose as electron donor.. [286]
78. C4烃催化裂解增产丙烯催化剂研究进展 [286]
79. 银纳米线的制备及电催化还原氧性能研究 [285]
80. BiAg Alloy Nanospheres: A New Photocatalyst for H-2 Evolution from.. [282]
81. Eosin Y/Pt/SiO2催化剂光催化还原水制氢 [281]
82. CdS/石墨烯复合材料的制备及其可见光催化分解水产氢性能 [280]
83. Promotion effect of lanthanum addition on the catalytic activity o.. [279]
84. Renewable hydrogen production by a mild-temperature steam reformin.. [278]
85. 莫高窟壁画盐害作用机理研究(Ⅱ) [277]
86. Enhancement of photocatalytic activity of cadmium sulfide for hydr.. [277]
87. 分子逻辑器件研究进展 [275]
88. Photo-catalytic H2 evolution over a series of Keggin-structure het.. [274]
89. High performance rare earth oxides LnOx(Ln = Sc, Y, La, Ce, Pr and.. [274]
90. Steam reforming of acetic acid over Ni/ZrO2 catalysts: Effects of .. [273]
91. 不同形貌CuxCd1-xS光催化剂光腐蚀性能差异研究 [270]
92. L-Arginine and zinc ion effect on recognition and hydrolysis rate .. [269]
93. Recognition and catalytic hydrolysis of adenosine 5′-triphosphate.. [268]
94. Co-Ni/SiO2催化剂催化乙酸重整制氢反应研究 [268]
95. Composition, morphology and photocatalytic activity of Zn-In-S com.. [267]
96. Photocatalytic H2 evolution over basic zincoxysulfide (ZnS1-x-0.5y.. [267]
97. A simple solution-phase reduction method for the synthesis of shap.. [267]
98. Highly ordered rectangular silver nanowire monolayers: water-assis.. [261]
99. Z-Scheme Photocatalytic System Utilizing Separate Reaction Centers.. [261]
100. Ni/Al2O3、Co/Al2O3和Ni-Co/Al2O3催化剂催化乙醇水蒸气重整制氢的性能 [260]

Downloads

1. Seizing solar hydrogen from water promoted by magic spin transport.. [56]
2. Morphology modulation of SrTiO3/TiO2 heterostructures for enhanced.. [11]
3. Ion exchange synthesis of PAN/Ag3PO4 core-shell nanofibers with en.. [10]
4. Influence of promoter on the catalytic activity of high p.. [9]
5. Low temperature CO oxidation over Pd-Ce catalysts supported on ZSM.. [9]
6. Low temperature carbon monoxide catalytic oxidation at the Pd/Ce-Z.. [8]
7. Modification of TiO2 with sulfate and phosphate for enhanced eosin.. [8]
8. A new method to construct hierarchical ZSM-5 zeolites with excelle.. [8]
9. 柴油车SCR脱硝金属氧化物催化剂研究进展 [8]
10. Visible Photocatalytic Water Splitting and Photocatalytic Two-Elec.. [7]
11. Study of One Step Synthesis of Rare Earth Zeolite (Ln–ZSM-5) and .. [6]
12. Electrocatalytic oxidation of carbon monoxide on platinum-modified.. [6]
13. Concave trisoctahedral Ag3PO4 microcrystals with high-index facets.. [6]
14. Eosin Y-sensitized graphitic carbon nitride fabricated by heating .. [6]
15. Fabrication and catalytic properties of Pd and Ce decorated carbon.. [6]
16. Influence of pore structures of a carbon support on the surface te.. [6]
17. Electric field-directed growth and photoelectrochemical properties.. [6]
18. Structural and Textural Characteristics of Zn-Containing ZSM-5 Zeo.. [6]
19. Synergistic effects of SrTiO3 nanocubes and Ti3+ dual-doping for h.. [6]
20. One pot synthesis of a highly efficient mesoporous ceria–titanium.. [6]
21. Carefully designed oxygen-containing functional groups and defects.. [6]
22. Recent Progress on Establishing Structure-Activity Relationship of.. [6]
23. Photocatalytic hydrogen generation in the presence of glucose over.. [5]
24. Morphology-dependent activity of silver nanostructures towards the.. [5]
25. Synthesis of CdS Nanorods by an Ethylenediamine Assisted Hydrother.. [5]
26. Selective Growth of Metallic Ag Nanocrystals on Ag3PO4 Submicro-Cu.. [5]
27. Remarkable enhancement of photocatalytic hydrogen evolution over C.. [5]
28. Effect of epimerization of d-glucose on photocatalytic hydrogen ge.. [5]
29. Butene catalytic cracking to ethylene and propylene on fluorinated.. [5]
30. Highly active Pd/Fe based catalyst prepared with polyol-red.. [5]
31. High performance rare earth oxides LnOx(Ln = Sc, Y, La, Ce, Pr and.. [5]
32. Vertically aligned ZnO nanowire arrays tip-grafted with silver nan.. [5]
33. 用于净化废气的催化剂 [5]
34. Influence of the pore structure of CeO2 supports on the surface te.. [5]
35. Deposition of Pd– Fe nanoparticles onto carbon spheres with contr.. [5]
36. Interface Charge Transfer versus Surface Proton Reduction: Which I.. [5]
37. Enhanced Catalytic Performance of Three-Dimensional Ordered Mesopo.. [5]
38. Effect of Different Pore Structures on the Surface Textures of the.. [5]
39. ZSM-5分子筛介孔的构筑 [5]
40. Intrinsic magnetic characteristics-dependent charge transfer and v.. [5]
41. Investigation of coating technology and catalytic performance over.. [5]
42. SiO2/曙红Y-Pt体系可见光催化分解水制氢研究 [5]
43. Synthesis and application of metal-containing ZSM-5 for the select.. [5]
44. Strongly coupled CdS/graphene quantum dots nanohybrids for highly .. [5]
45. Water splitting by CdS/Pt/WO3-CeOx photocatalysts with assisting o.. [5]
46. Water splitting over core-shell structural nanorod CdS@Cr2O3 catal.. [5]
47. The enhancement of CdS photocatalytic activity for water splitting.. [5]
48. 溶剂热法在金属氧化物和分子筛及贵金属等催化剂制备中的应用研究进展 [5]
49. Ni-Mo-S nanoparticles modified graphitic C3N4 for efficient hydrog.. [5]
50. Bio-oil steam reforming, partial oxidation or oxidative steam refo.. [4]
51. 助剂改性对贵金属催化剂CO 选择氧化活性中心的影响 [4]
52. Investigation of the steam reforming of a series of model compound.. [4]
53. High performance rare earth oxides LnOx (Ln = La, Ce, Nd, Sm and D.. [4]
54. Morphology-controlled preparation of silver nanocrystals and their.. [4]
55. 回收低浓度金的方法 [4]
56. Selective growth of Ag3PO4 submicro-cubes on Ag nanowires to fabri.. [4]
57. Photocatalytic hydrogen generation in the presence of ethanolamine.. [4]
58. 低成本原料一步直接合成小晶粒ZSM-5分子筛(英文) [4]
59. Visible-light-driven photoelectrochemical and photocatalytic perfo.. [4]
60. Facile synthesis of tetrahedral Ag3PO4 submicro-crystals with enha.. [4]
61. BiAg Alloy Nanospheres: A New Photocatalyst for H-2 Evolution from.. [4]
62. New facile synthesis of one-dimensional Ag@TiO2 anatase core-shell.. [4]
63. Enhanced photocatalytic properties of biomimetic Ag/AgCl heterostr.. [4]
64. Highly efficient hydrogen production from alkaline aldehyde soluti.. [4]
65. Direct conversion of Bi nanospheres into 3D flower-like BiOBr nano.. [4]
66. Surface texture and physicochemical characterization of mesoporous.. [4]
67. Promotion of redox and stability features of doped Ce-W-Ti for NH3.. [4]
68. Hydrogen production by H2S photodecomposition on ZnFe2O4 catalyst [4]
69. Ni对Cu/ZnO基甲醇裂解催化剂的促进机制 [4]
70. Highly ordered rectangular silver nanowire monolayers: water-assis.. [3]
71. Control growth of uniform platinum nanotubes and their catalytic p.. [3]
72. SiO2复合Pt-Cd0.53Zn0.47S 固溶体的光催化性能 [3]
73. Preparation of SiO2-Pt-CdS composite photocatalyst and its photoca.. [3]
74. Sites for High Efficient Photocatalytic Hydrogen Evolution on a Li.. [3]
75. Dye-cosensitized graphene/Pt photocatalyst for high efficient visi.. [3]
76. Two-dimensional dendritic Ag3PO4 nanostructures and their photocat.. [3]
77. A simple solution-phase reduction method for the synthesis of shap.. [3]
78. The effect of plasma pre-treatment of carbon used as a Pt catalyst.. [3]
79. Size-controlled synthesis of colloidal platinum nanoparticles and .. [3]
80. 直接甲醇燃料电池阳极电催化剂 [3]
81. The long-term photocatalytic stability of Co2+-modified P25-TiO2 p.. [3]
82. Facile and Rapid Oxidation Fabrication of BiOCl Hierarchical Nanos.. [3]
83. Enhanced photocatalytic activity of Ag/Ag3PO4 coaxial hetero-nanow.. [3]
84. Fabrication of Ag3PO4–PAN composite nanofibers for photocatalytic.. [3]
85. Photosensitization of SiW11O398--modified TiO2 by Eosin Y for stab.. [3]
86. Promoted photoinduced charge separation and directional electron t.. [3]
87. Modification of ZnS1-x-0.5yOx(OH)(y)-ZnO photocatalyst with NiS fo.. [3]
88. TiO2 Photocatalytic Materials 2013 [3]
89. TiO2 Nanotube Arrays Modified with Cr- Doped SrTiO3 Nanocubes for .. [3]
90. 丙烷部分氧化制氢催化剂及其制备方法和应用 [3]
91. Photo-directed growth of Au nanowires on ZnO arrays for enhancing .. [3]
92. Highly efficient hydrogen production from formaldehyde over Ag/gam.. [3]
93. Bi2O3修饰的BiPO4纳米棒复合催化剂可见光光催化性能的研究 [3]
94. 氧化锆负载的铂-钌、铂和钌催化剂对一甲胺的选择性催化氧化(英文) [3]
95. Fabrication of porous carbon spheres and as support for the applic.. [3]
96. Feature Designed Growth of 3D Flower-like SiO2 Growing on Polyethy.. [3]
97. Modulating and controlling active species dispersion over Ni-Co bi.. [3]
98. Graphene supported Co-Mo-P catalyst for efficient photocatalyzed h.. [3]
99. Hard-template synthesis of three-dimensional mesoporous Cu-Ce base.. [3]
100. Controlled pore size of 3D mesoporous Cu-Ce based catalysts and in.. [3]