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2015/04/24 | 點擊: | 【 【打印】【關閉】

  1.Zhu, J., et al., Highly polarized carbon nano-architecture as robust metal-free catalyst for oxygen reduction in polymer electrolyte membrane fuel cells. Nano Energy, 2018. 49: p. 23-30. 

  2.Xiao, M.L., et al., Microporous Framework Induced Synthesis of Single-Atom Dispersed Fe-N-C Acidic ORR Catalyst and Its in Situ Reduced Fe-N-4 Active Site Identification Revealed by X-ray Absorption Spectroscopy. Acs Catalysis, 2018. 8(4): p. 2824-2832. 

  3.Xiao, M.L., et al., Identification of binuclear Co2N5 active sites for oxygen reduction reaction with more than one magnitude higher activity than single atom CoN4 site. Nano Energy, 2018. 46: p. 396-403. 

  4.Lv, Q., et al., Pd-PdO Interface as Active Site for HCOOH Selective Dehydrogenation at Ambient Condition. Journal of Physical Chemistry C, 2018. 122(4): p. 2081-2088. 

  5.Luo, Z.Y., et al., Chemically activating MoS2 via spontaneous atomic palladium interfacial doping towards efficient hydrogen evolution. Nature Communications, 2018. 9. 

  6.Li, K., et al., Enhanced electrocatalytic performance for the hydrogen evolution reaction through surface enrichment of platinum nanoclusters alloying with ruthenium in situ embedded in carbon. Energy & Environmental Science, 2018. 11(5): p. 1232-1239. 

  7.Li, K., et al., Platinum nanoparticles partially-embedded into carbon sphere surfaces: a low metal-loading anode catalyst with superior performance for direct methanol fuel cells. Journal of Materials Chemistry A, 2017. 5(37): p. 19857-19865. 

  8.Li, G.Q., et al., Nanoporous IrO2 catalyst with enhanced activity and durability for water oxidation owing to its micro/mesoporous structure. Nanoscale, 2017. 9(27): p. 9291-9298. 

  9.Chang, J.F., et al., Core-shell structured Ni12P5/Ni-3(PO4)(2) hollow spheres as difunctional and efficient electrocatalysts for overall water electrolysis. Applied Catalysis B-Environmental, 2017. 204: p. 486-496. 

  10.Zhu, J., et al., Metal-Organic Framework-Induced Synthesis of Ultrasmall Encased NiFe Nanoparticles Coupling with Graphene as an Efficient Oxygen Electrode for a Rechargeable Zn-Air Battery. Acs Catalysis, 2016. 6(10): p. 6335-6342. 

  11.Zhu, J., et al., Active Pt3Ni (111) Surface of Pt3Ni Icosahedron for Oxygen Reduction. Acs Applied Materials & Interfaces, 2016. 8(44): p. 30066-30071. 

  12.Chang, J., et al., Ultrathin cobalt phosphide nanosheets as efficient bifunctional catalysts for a water electrolysis cell and the origin for cell performance degradation. Green Chemistry, 2016. 18(8): p. 2287-2295. 

  13.Zhu, J., et al., Strongly coupled Pt nanotubes/N-doped graphene as highly active and durable electrocatalysts for oxygen reduction reaction. Nano Energy, 2015. 13: p. 318-326. 

  14.Zhu, J., et al., Growth mechanism and active site probing of [email protected] carbon nanotubes/C catalysts: guidance for building highly efficient oxygen reduction electrocatalysts. Journal of Materials Chemistry A, 2015. 3(43): p. 21451-21459. 

  15.Feng, L., et al., Nanostructured PtRu/C catalyst promoted by CoP as an efficient and robust anode catalyst in direct methanol fuel cells. Nano Energy, 2015. 15: p. 462-469. 

  16.Chang, J.F., et al., Surface Oxidized Cobalt-Phosphide Nanorods As an Advanced Oxygen Evolution Catalyst in Alkaline Solution. ACS Catalysis, 2015. 5(11): p. 6874-6878. 

  17.Hu, Y., et al., Hollow Spheres of Iron Carbide Nanoparticles Encased in Graphitic Layers as Oxygen Reduction Catalysts. Angewandte Chemie-International Edition, 2014. 53(14): p. 3675-3679. 

  18.Chang, J., et al., An Effective Pd-Ni2P/C Anode Catalyst for Direct Formic Acid Fuel Cells. Angewandte Chemie-International Edition, 2014. 53(1): p. 122-126. 

  19.Chang, J., et al., Ni2P enhances the activity and durability of the Pt anode catalyst in direct methanol fuel cells. Energy & Environmental Science, 2014. 7(5): p. 1628-1632. 

  20.Zhao, X., et al., Recent advances in catalysts for direct methanol fuel cells. Energy & Environmental Science, 2011. 4(8): p. 2736-2753. 

    21.Zhu, J., et al., Highly polarized carbon nano-architecture as robust metal-free catalyst for oxygen reduction in polymer electrolyte membrane fuel cells. Nano Energy, 2018. 49: p. 23-30.

    22.Xiao, M.L., et al., Microporous Framework Induced Synthesis of Single-Atom Dispersed Fe-N-C Acidic ORR Catalyst and Its in Situ Reduced Fe-N-4 Active Site Identification Revealed by X-ray Absorption Spectroscopy. Acs Catalysis, 2018. 8(4): p. 2824-2832.

    23.Xiao, M.L., et al., Identification of binuclear Co2N5 active sites for oxygen reduction reaction with more than one magnitude higher activity than single atom CoN4 site. Nano Energy, 2018. 46: p. 396-403.

    24.Lv, Q., et al., Pd-PdO Interface as Active Site for HCOOH Selective Dehydrogenation at Ambient Condition. Journal of Physical Chemistry C, 2018. 122(4): p. 2081-2088.

    25.Luo, Z.Y., et al., Chemically activating MoS2 via spontaneous atomic palladium interfacial doping towards efficient hydrogen evolution. Nature Communications, 2018. 9.

    26.Li, K., et al., Enhanced electrocatalytic performance for the hydrogen evolution reaction through surface enrichment of platinum nanoclusters alloying with ruthenium in situ embedded in carbon. Energy & Environmental Science, 2018. 11(5): p. 1232-1239.

    27.Li, K., et al., Platinum nanoparticles partially-embedded into carbon sphere surfaces: a low metal-loading anode catalyst with superior performance for direct methanol fuel cells. Journal of Materials Chemistry A, 2017. 5(37): p. 19857-19865.

    28.Li, G.Q., et al., Nanoporous IrO2 catalyst with enhanced activity and durability for water oxidation owing to its micro/mesoporous structure. Nanoscale, 2017. 9(27): p. 9291-9298.

    29.Chang, J.F., et al., Core-shell structured Ni12P5/Ni-3(PO4)(2) hollow spheres as difunctional and efficient electrocatalysts for overall water electrolysis. Applied Catalysis B-Environmental, 2017. 204: p. 486-496.

    30.Zhu, J., et al., Metal-Organic Framework-Induced Synthesis of Ultrasmall Encased NiFe Nanoparticles Coupling with Graphene as an Efficient Oxygen Electrode for a Rechargeable Zn-Air Battery. Acs Catalysis, 2016. 6(10): p. 6335-6342.

    31.Zhu, J., et al., Active Pt3Ni (111) Surface of Pt3Ni Icosahedron for Oxygen Reduction. Acs Applied Materials & Interfaces, 2016. 8(44): p. 30066-30071.

    32.Chang, J., et al., Ultrathin cobalt phosphide nanosheets as efficient bifunctional catalysts for a water electrolysis cell and the origin for cell performance degradation. Green Chemistry, 2016. 18(8): p. 2287-2295.

    33.Zhu, J., et al., Strongly coupled Pt nanotubes/N-doped graphene as highly active and durable electrocatalysts for oxygen reduction reaction. Nano Energy, 2015. 13: p. 318-326.

    34.Zhu, J., et al., Growth mechanism and active site probing of [email protected] carbon nanotubes/C catalysts: guidance for building highly efficient oxygen reduction electrocatalysts. Journal of Materials Chemistry A, 2015. 3(43): p. 21451-21459.

    35.Feng, L., et al., Nanostructured PtRu/C catalyst promoted by CoP as an efficient and robust anode catalyst in direct methanol fuel cells. Nano Energy, 2015. 15: p. 462-469.

    36.Chang, J.F., et al., Surface Oxidized Cobalt-Phosphide Nanorods As an Advanced Oxygen Evolution Catalyst in Alkaline Solution. ACS Catalysis, 2015. 5(11): p. 6874-6878.

    37.Hu, Y., et al., Hollow Spheres of Iron Carbide Nanoparticles Encased in Graphitic Layers as Oxygen Reduction Catalysts. Angewandte Chemie-International Edition, 2014. 53(14): p. 3675-3679.

    38.Chang, J., et al., An Effective Pd-Ni2P/C Anode Catalyst for Direct Formic Acid Fuel Cells. Angewandte Chemie-International Edition, 2014. 53(1): p. 122-126.

    39.Chang, J., et al., Ni2P enhances the activity and durability of the Pt anode catalyst in direct methanol fuel cells. Energy & Environmental Science, 2014. 7(5): p. 1628-1632.

    40.hao, X., et al., Recent advances in catalysts for direct methanol fuel cells. Energy & Environmental Science, 2011. 4(8): p. 2736-2753.

 

  

  

 
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