zdxkChs
category
工学
xkOne
化学工程与技术
xkTwo
化学工程"},{"category
工学
xkOne
材料科学与工程（可授工学、理学学位）
xkTwo
材料物理与化学"}],"GH
XM
沈培康
CSRQ
XBM
1
DWH
60500
pic
http://prof.gxu.edu.cn/teacher-info/user-images/**_20**0.gif
zzmm
中国党员
jiguan
zhicheng
教授
topedu
博士研究生
ZHXWMC
博士
zhiwu
tel

yzbm
530004
email
pkshen@gxu.edu.cn
qq

weixin

address
广西南宁大学东路100号广西大学可再生能源材料协同创新中心
iscampus
2
dslb
博士后合作导师, 博士研究生导师, 硕士研究生导师
zdxkmlbh
08
zdyjxkbh
0817
zdejxkbh
081701
dwh1
30400
zdxkmlbh2
08
zdyjxkbh2
0805
zdejxkbh2
080501
dwh2
30900
zyyjfx
tbzrr
尹诗斌
isadmin
0
isview
0
firstLetter
cs
jzgdqzt
11
sjgxrq":**00,"forEditDwmc
可再生能源材料协同创新中心
dwUrl":null},"showInfo":{"GH
show_CSRQ
1
show_zzmm
0
show_jiguan
1
show_zhicheng
0
show_tel
0
show_yzbm
0
show_email
0
show_qq
0
show_weixin
0
show_address
0
show_topedu
0
show_ZHXWMC
0"},"largeMsg":{"GH
**
zyxxjx
1982年初毕业于厦门大学电化学专业并留校任教。1989年赴英国工作学习，1992年获英国Essex大学博士学位。在国外工作期间曾与英国的Rolls Royce公司合作研究潜艇燃料电池、与Lion公司合作研究酒精传感器、受英国工贸部（DTI）基金资助研究直接甲醇燃料电池催化剂、得到英国研究经费资助并与挪威的Kvaerner FSSL公司合作研制海水电池等。自2001年底受聘中山大学物理科学与工程技术学院教授以来，建立了稳定的研究团队。已承担国家863项目、国家基金委-广东省联合项目、国际重大合作项目、国家自然科学基金项目、广东省重大科研项目、广东省教育部产学研项目、广州市重点科技项目及企业合作项目等各类基础研究和攻关项目四十余项。
xsjz
国际电化学学会会员、英国化学会会员、特许化学家、美国化学学会会员、美国电化学学会会员、中国电化学委员会燃料电池分会主席。
zyyjskc
《材料化学》、《电化学》
zyyjfx
（1）材料物理与化学，包括电化学基础和技术、微观电化学；（2）新型能源技术，包括燃料电池和高能电源技术；（3）纳米材料和应用技术，包括纳米功能材料和器件。
zckyxm
已承担国家863项目、国家基金委-广东省联合项目、国际重大合作项目、国家自然科学基金项目、广东省重大科研项目、广东省教育部产学研项目、广州市重点科技项目及企业合作项目等各类基础研究和攻关项目四十余项。沈培康教授注重国内外的学术交流及合作，注重产学研结合，瞄准国家需求，非常重视成果的产业化转化，已经扶持国内外两个燃料电池企业进行批量生产燃料电池发电系统，与上海汽车有限公司合作进行燃料电池催化剂的批量生产、与广州汽车集团公司进行电动汽车能源材料和技术的创新研究。在国际合作方面，目前正承担美国通用汽车公司、日本Shin Kobe公司、丹麦政府等的合作项目进行新能源关键材料研究和产业化。 近五年承担的重要项目列表：1. 2015.8-2020.8，广东省团队项目，300万。2. 2015.1.1-2019.12.30，国家重大科学研究计划《面向车用燃料电池的纳米-介观-宏观多级结构的电催化体系的研究--新型多级结构高性能膜电极的构建及应用》，项目编号：2015CB932304，576万。3. 2014.7.1-2017.6.30，广汽《三维多级孔类石墨烯及硫电极材料应用于高稳定锂-硫电池的示范应用研究》，项目编号：XW6，150万。4. 2014.7.1-2017.6.30，广汽《基于三维多级孔类石墨烯材料的燃料电池新型催化剂和膜组装电极》，项目编号：XW6，300。5. 2013.01-2017.12，国家基金委国际重大合作项目《新型多元金属碳化物纳米结构能源材料及功能调控研究》，项目编号：**，280万。6. 2010.11-2015.11，日本新神户公司项目《铅酸电池正极集电体的电化学行为研究》，600万日元+800万日元。7. 2011.1-2014.12，国家基金委-广东联合重点项目《低温燃料电池催化材料的共性物理化学问题和催化本质研究》，项目编号：U**，190万。8. 2011.1-2013.12，国家自然科学基金项目《碳化钨（钒、钼）基催化材料的定域制备及电催化增强机理研究》，项目编号：**，37万。9. 2010.7-2012.6，国家863重点《5KW级燃料电池关键材料和系统集成技术开发》，项目编号：2009AA034400，83.3万。10. 2009.11-2013.11，美国通用《碳化钨基Pt或非Pt氧还原催化剂》，20万美元。
qdcg
lw
已在Chem. Rev.; Chem. Soc. Rev.; J. Am. Chem. Soc.; Adv. Mater.; Adv. Funct. Mater.; Energy Environ. Sci.; Adv. Energy Mater., ACS Nano, Chem. Commun.; J. Phys. Chem.; J. Mater. Chem.;Electrochem. Commun.; J. Power Sources 等期刊发表学术论文超过300篇，其中SCI论文超过260篇（他引超7000次）、累计ESI（Highly Cited Papers, 1%）论文22篇，其中0.1% Hot Papers 2篇，H因子49。中国高被引****能源领域列第2位。另外，参与四本英文专著编写、申请和授权发明专利四十余件。2002年获国务院政府特殊津贴、2011年获广东省科学技术一等奖，2013年获国家自然科学奖二等奖。近五年文章列表：（IF大于5）2015: Cited 1565 times. 1. Shuang Xu, Jun Gao, Linlin Wang, Kan Kan, Yu Xie, Pei Kang Shen, Li Li, Keying Shi, Role of the heterojunctions in In2O3-composite SnO2 nanorod sensors and their remarkable gas-sensing performance for NOx at room temperature, Nanoscale, 7, 14643-14651 (2015). IF=7.3942. Yanshuo Jin, Pei Kang Shen, Nanoflower-like metallic conductive MoO2 as a high-performance non-precious metal electrocatalyst for the hydrogen evolution reaction, J. Mater. Chem. A, 3, 20080-20085 (2015). IF=7.4433. Zaoxue Yan, Mingmei Zhang, Jimin Xie, Pei Kang Shen, An ultrastable bimetallic carbide as platinum electrocatalyst support for highly active oxygen reduction reaction, J. Power Sources, 295, 156–161 (2015). IF=6.2174. Jin Zhang, Shanfu Lu, Yan Xiang, Pei Kang Shen, Jian Liu, San Ping Jiang, Carbon-Nanotubes-Supported Pd Nanoparticles for Alcohol Oxidations in Fuel Cells: Effect of Number of Nanotube Walls on Activity, ChemSusChem, 8, 2956–2966 ( 2015). IF=7.6575. Zaoxue Yan, Jimin Xie, Pei Kang Shen, Hollow molybdenum carbide sphere promoted Pt electrocatalyst for oxygen reduction and methanol oxidation reaction, J. Power Sources 286, 239-246 (2015). IF=6.2176. P.K. Shen, C.Y. He, S.Y. Chang, X.D. Huang, Z.Q. Tian, Magnéli phase Ti8O15 nanowires as conductive carbon-free energy materials to enhance the electrochemical activity of palladium nanoparticles for direct ethanol oxidation, J. Mater. Chem. A, 3, 14416-14423 (2015). IF=7.4437. M. Chen, X.L. Jiang, H. Yang and P.K. Shen, Performance improvement of air electrode for Li/air batteries by hydrophobicity adjustment, J. Mater. Chem. A, 3, 11874–11879 (2015). IF=7.4438. J.H. Cheng, J.L. Zhu, X.L. Wei, P.K. Shen, Ce2O2S anchored on graphitized carbon with tunable architectures as a new promising anode for Li-ion batteries, J. Mater. Chem. A, 3, 10026 – 10030 (2015). IF=7.4439. Y.Y. Li,, H.Y. Zhang, P.K. Shen, Ultrasmall metal oxide nanoparticles anchored on three-dimensional hierarchical porous gaphene-like networks as anode for high-performance lithium ion batteries, Nano Energy, 13,563-572 (2015). IF=10.32510. J.L. Zhu, G.Q. He, P.K. Shen, A cobalt phosphide on carbon decorated Pt catalyst with excellent electrocatalytic performance for direct methanol oxidation, J. Power Sources, 275, 279-283 (2015). IF=6.21711. Y. Cheng, C.W. Xu, L.C. Jia, J.D. Gale, L.L. Zhang, C. Liu, P.K. Shen, S.P. Jiang, Pristine carbon nanotubes as non-metal electrocatalysts for oxygen evolution reaction of water splitting, Appl. Catal. B: Environ., 163, 96–104 (2015). IF=7.43512. J.H Cheng, Y.Y. Li, X.D. Huang, Q.Q Wang, A. Mei, P.K. Shen, Highly stable electrocatalysts supported on nitrogen-self-doped three-dimensional graphene-like networks with hierarchical porous structure, J. Mater. Chem. A, 3, 1492–1497 (2015). IF=7.44313. W.Y. Yuan, Y. Cheng, P.K. Shen, C.M. Li, S.P. Jiang, Significance of wall number on the carbon nanotube support-promoted electrocatalytic activity of Pt NPs towards methanol/formic acid oxidation reactions in direct alcohol fuel cells, J. Mater. Chem. A, 3, 1961–1971 (2015). IF=7.443 14. X. Wen, X.L. Wei, L.W. Yang, P.K. Shen, Self-assembled FeS2 cubes anchored on reduced graphene oxide as anode material for lithium ion batteries, J. Mater. Chem. A, 3, 2090–2096 (2015). IF=7.443 15. C.Y. He, S.Y. Chang, X.D. Huang, Q.Q. Wang, A. Mei, P.K. Shen, Direct synthesis of pure single-crystalline magnéli phase Ti8O15 nanowires as conductive carbon-free material for electrocatalysis, Nanoscale, 7, 2856-2861 (2015). IF=7.394 16. Z.X. Yan, M.M. Zhang, J.M. Xie, J.J. Zhu, S.P. Shen, A bimetallic carbide Fe2MoC promoted Pd electrocatalyst with performance superior to Pt/C towards the oxygen reduction reaction in acidic media, Appl. Catal. B: Environ., 165, 636–641 (2015). IF=7.43517. X. Ding S.B. Yin, K. An, L. Luo, N. Shi, Y.H. Qiang, S. Pasupathi, B. G. Pollet, P.K. Shen, FeN stabilized FeN@Pt core–shell nanostructures for oxygen reduction reaction, J. Mater. Chem. A, 3, 4462–4469 (2015). IF=7.443 2014: Cited 1543 times.18. Y. Cheng, C.W. Xu, P. K. Shen, S. P. Jiang, Effect of nitrogen-containing functionalization on the electrocatalytic activity of PtRu nanoparticles supported on carbon nanotubes for direct methanol fuel cells, Appl. Catal. B: Environ., 158–159, 140–149 (2014). IF=7.43519. J. Zhang, Y. Cheng, S.F. Ku, L.C. Jia, P.K. Shen, S.P. Jiang, Significant promotion effect of carbon nanotubes on the electrocatalytic activity of supported Pd NPs for ethanol oxidation reaction of fuel cells: the role of inner tubes，Chem. Commun. 50, 13732-13734 (2014). IF=6.83420. Z.S. Li, S. Ji, B.G. Pollet, P.K. Shen, Co3W3C promoted Pd catalyst exhibiting competitive performance to Pt/C catalyst towards the oxygen reduction reaction, Chem. Commun., 50, 566-568 (2014). IF=6.834 21. W.Y. Yuan, P.K. Shen, S.P. Jiang, Controllable synthesis of graphene supported MnO2 nanowires via self-assembly for enhanced water oxidation in both alkaline and neutral solutions, J. Mater. Chem. A, 2, 123-129 (2014). IF=7.443 22. J. Gao, L.L. Wang, K. Kan, S. Xu, L.Q. Jing, S.Q. Liu, P.K. Shen, L. Li, K.Y. Shi, One-step synthesis of mesoporous Al2O3-In2O3 nanofibres with remarkable gas-sensing performance to NOx at room temperature, J. Mater. Chem. A, 2, 949-956 (2014). IF=7.443 23. J.L. Zhu, Y.Y. Li, S. Kang, X.L. Wei, P.K. Shen, One-step synthesis of Ni3S2 nanoparticles wrapped by in situ generated nitrogen-self-doped graphene sheets with highly improved electrochemical properties in Li-ion batteries, J. Mater. Chem. A, 2 (9), 3142 – 3147 (2014). IF=7.44324. Y.Y. Li, Q.W. Zhang, J.L. Zhu, X.L. Wei, P.K. Shen, An extremely stable MnO2 anode incorporated with 3D porous graphene-like networks for lithium-ion batteries, J. Mater. Chem. A, 2 (9), 3163 – 3168 (2014). IF=7.443 25. C.Y. He, J.J. Zhang, P.K. Shen, Nitrogen-self-doped graphene-based non-precious metal catalyst with superior performance to Pt/C catalyst toward oxygen reduction reaction, J. Mater. Chem. A, 2 (9), 3231 - 3236 (2014). IF=7.44326. Z.X. Yan, G.Q. He, P.K. Shen, Z.B. Luo, J.M. Xie, M. Chen, MoC-graphite composite as Pt electrocatalyst support for highly active methanol oxidation and oxygen reduction reaction, J. Mater. Chem. A, 2, 4014–4022 (2014). IF=7.443 27. Y.Y. Li, Z.S. Li, Q.W. Zhang, P.K. Shen, Sulfur-infiltrated three-dimensional graphene-like material with hierarchical pores for highly stable lithium-sulfur batteries, J. Mater. Chem. A, 2(13), 4528–4533 (2014). IF=7.443 28. L.F. Dang, G. Zhang, K. Kan, Y.F. Lin, F.Q. Bai,L.Q. Jing, P.K. Shen, L. Li, K.Y. Shi, Heterostructured Co3O4/PEI-CNTs Composite: Fabrication, Characterization and CO Gas Sensors at Room Temperature, J. Mater. Chem. A, 2, 4558-4565 (2015). IF=7.44329. Y.L. Ge, K. Kan, Y. Yang, L. Zhou, L.Q. Jing, P.K. Shen, L. Li, K.Y. Shi, Highly mesoporous hierarchical nickel and cobalt double hydroxide composite: fabrication, characterization and ultrafast NOx gas sensors at room temperature, J. Mater. Chem. A, 2(14), 4961-4969 (2014). IF=7.443 30. C.Y. He, P.K. Shen, Pt loaded on truncated hexagonal pyramid WC/graphene for oxygen reduction reaction, Nano Energy, 8, 52-61 (2014). IF=10.32531. Z.S. Li, Y.Y. Li, S. P. Jiang, G.Q. He, P. K. Shen, Novel graphene-like nanosheet supported highly active electrocatalysts with ultralow Pt loadings for oxygen reduction reaction, J. Mater. Chem. A, 2, 16898–16904 (2014). IF=7.44332. J.L. Zhu, S.P. Jiang, R.H. Wang, K.Y. Shi, P.K. Shen, One-pot synthesis of a nitrogen and phosphorus dual-doped carbon nanotube array as a highly effective electrocatalyst for the oxygen reduction reaction, J. Mater. Chem. A, 2, 15448-15453 (2014). IF=7.4432013: Cited 1278 times.33. Y.Y. Li, Z.S. Li, P.K. Shen, Simultaneous formation of ultrahigh surface area and three-dimensional hierarchical porous graphene-like networks for fast and highly stable supercapacitors, Adv. Mater. 25, 2474-2480 (2013). IF=17.49334. J.L. Zhu, C.Y. He, Y.Y. Li, S. Kang, P.K. Shen, One-step synthesis of boron and nitrogen-dual-self-doped graphene sheets as non-metal catalysts for oxygen reduction reaction, J. Mater. Chem. A, 1, 14700-14705 (2013). IF=7.44335. C.Y. He, R.H. Wang, H.G. Fu, P.K. Shen, Nitrogen-self-doped graphene as a high capacity anode material for lithium-ion batteries, J. Mater. Chem. A, 1, 14586-14591 (2013). IF=7.44336. J. Zeng, B.B. He, K. Lamb, R. De Marco, P.K. Shen, S.P. Jiang, Anhydrous phosphoric acid functionalized sintered mesoporous silica nanocomposite proton exchange membranes for fuel cells, ACS Appl. Mater. Interfaces, 5, 11240−11248 (2013). IF=6.72337. Z. X. Yan, M. M. Zhang, J. M. Xie, P.K. Shen, Vanadium carbide and graphite promoted Pd electrocatalyst for ethanol oxidation in alkaline media, J. Power Sources, 243, 336-342 (2013). IF=5.21138. J. Zeng, B.B. He, K. Lamb, R. De Marco, P.K. Shen, S.P. Jiang, Phosphoric acid functionalized pre-sintered meso-silica for high temperature proton exchange membrane fuel cells, Chem. Commun., 49, 4655—4657 (2013). IF=6.83439. Z.X. Yan, G.Q. He, M. Cai, H. Meng, P.K. Shen, Formation of tungsten carbide nanoparticles on graphitized carbon to facilitate the oxygen reduction reaction, J. Power, Sources, 242, 817-823 (2013). IF=6.21740. C.Y. He, Z.S. Li, M.L. Cai, M. Cai, J.Q. Wang, Z.Q. Tian, X. Zhang, P.K. Shen, A strategy for mass production of self-assembled nitrogen-doped graphene as catalytic materials, J. Mater. Chem. A, 1, 1401–1406 (2013). IF=7.443 41. C. Y. He, S. P. Jiang, P. K. Shen, Large-scale and rapid synthesis of disk-shaped and nano-sized graphene, Sci. Rep-UK, 3, 2144 (2013). IF=5.57842. Z.X. Yan, M. Cai, P. K. Shen, Nanosized tungsten carbide synthesized by a novel route at low temperature for high performance electrocatalysis, Sci. Rep-UK, 3, 1646 (2013). IF=5.5782012: Cited 1043 times.43. H. W. Zhang, P.K. Shen, Recent development of polymer electrolyte membranes for fuel cells, Chem. Rev. 112, 2780−2832 (2012). IF=46.568 44. H. W. Zhang, P.K. Shen, Advances in the high performance polymer electrolyte membranes for fuel cells, Chem. Soc. Rev., 41, 2382–2394 (2012). IF=33.38345. J.J. Cai, Z.S. Li, P.K. Shen, Porous SnS nanorods/carbon hybrid materials as highly stable and high capacity anode for Li-ion batteries, ACS Appl. Mater. Interfaces, 4, 4093−4098 (2012). IF=6.72346. G.Q. He, Z.X. Yan, M. Cai, P.K. Shen, M.-R. Gao, H.-B. Yao, S.-H. Yu, Ion-exchange-assisted synthesis of Pt-VC nanoparticles loaded on graphitized carbon: A high-performance nanocomposite electrocatalyst for oxygen-reduction reactions, Chem-Eur. J. 18, 8490 – 8497 (2012). IF=5.73147. R.H. Wang, Y. Xie, K.Y. Shi, J.Q. Wang, C.G. Tian, P.K. Shen, H.G. Fu, Small-sized and contacting Pt-WC nanostructures on graphene as highly efficient anode catalysts for direct methanol fuel cells, Chem-Eur. J. 18, 7443 – 7451 (2012). IF=5.73148. Z.X. Yan, H. Meng, P.K. Shen, R.H. Wang , L. Wang , K.Y. Shi, H.G. Fu, A facile route to carbide-based electrocatalytic nanocomposites, J. Mater. Chem., 22, 5072-5079 (2012). IF=7.443 49. J.L. Lu, Z.H. Li, S. P. Jiang, P.K. Shen, L.Li, Nanostructured tungsten carbide/carbon composite synthesized by a microwave heating method as supports of platinum catalysts for methanol oxidation, J. Power Sources, 202, 56-62 (2012). IF=5.21150. X. M. Ma, H. Meng, M. Cai, P.K. Shen, Bimetallic carbide nanocomposite enhanced Pt catalyst with high activity and stability for the oxygen reduction reaction, J. Am. Chem. Soc. 134, 1954-1957 (2012). IF=12.113 51. Z. X. Yan, M. Cai, P. K. Shen, Low temperature formation of porous graphitized carbon for electrocatalysis, J. Mater. Chem., 22, 2133-2137 (2012). IF=7.4432011：52. Z. Q. Tian, S. H. Lim, C. K. Poh, Z. Tang, Z. Xia, Z. Luo, P.K. Shen, D. Chua, Y. P. Feng, Z. Shen, J. Lin, A highly order-structured membrane electrode assembly with vertically aligned carbon nanotubes for ultra-low Pt loading PEM fuel cells, Adv. Energy Mater., 1, 1205-1214, (2011). IF=16.14653. G. Wu, M. Nelson, S. G. Ma, H. Meng, G. F. Cui, P.K. Shen, Synthesis of nitrogen-doped onion-like carbon and its use in carbon-based CoFe binary non-precious-metal catalysts for oxygen-reduction, Carbon, 49, 3972-3982 (2011). IF=5.86854. Z. X. Yan, M. Cai, P. K. Shen, An ion exchange route to produce carbon supported nanoscale vanadium carbide for electrocatalysis, J. Mater. Chem., 21, 19166-19170 (2011). IF=7.443 55. S.G. Chen, Z. D. Wei, L. Guo, W. Ding, L.C. Dong, P.K. Shen, X.Q. Qi, L. Li, Enhanced dispersion and durability of Pt nanoparticles on a thiolated CNT support， Chem. Commun., 47, 10984–10986 (2011). IF=6.71856. Y. Sun, H. Cui, L. Gong, J. Chen, P. K. Shen, C. X. Wang, Field nanoemitter: One-dimension Al4C3 ceramics, Nanoscale, 3, 2978-2982 (2011). IF=6.92557. H. Meng, F. Xie, J. Chen, P. K. Shen, Electrodeposited palladium nanostructure as novel anode for direct formic acid fuel cell, J. Mater. Chem. 21, 11352 - 11358 (2011). IF=6.626 58. G. Q. He, Z. X. Yan, X. M. Ma, H. Meng, P.K. Shen, C. X. Wang, A universal method to synthesize nanoscale carbides as electrocatalyst supports towards oxygen reduction reaction, Nanoscale, 3, 3578-3582 (2011). IF=6.925 59. G. F. Cui, P.K. Shen, H. Meng, J. Zhao, G. Wu, Tungsten carbide as supports for Pt electrocatalysts with improved CO tolerance in methanol oxidation, J. Power Sources, 196, 6125–6130 (2011). IF=5.21160. H. Meng, C. X. Wang, P.K. Shen, G. Wu, Palladium thorn clusters as catalysts for electrooxidation of formic acid, Energy Environ. Sci., 4, 1522–1526 (2011). IF=20.52361. Y. Sun, H. Cui, L. Gong, J. Chen, J. She, Y. Ma, P.K. Shen, C. X. Wang, Carbon-in-Al4C3 nanowire superstructures for field emitters, ACS Nano, 5, 932–941 (2011). IF=12.88162. S. B. Yin, M. Cai, C. X. Wang, P.K. Shen, Tungsten carbide promoted Pd–Fe as alcohol-tolerant electrocatalysts for oxygen reduction reactions, Energy Environ. Sci., 4, 558-563 (2011). IF=20.52363. H. Meng, F.Y. Xie, J. Chen, S.H. Sun, P. K. Shen, Morphology controllable growth of Pt nanoparticles/nanowires on carbon powders and its application as novel electro-catalyst for methanol oxidation, Nanoscale, 3, 5041-5048, (2011). IF=6.9252010： 64. Y. X. Zhou, H. B. Yao, Y. Wang, H. L. Liu, M. R. Gao, P.K. Shen, S. H. Yu, Hierarchical hollow Co9S8 microspheres: solvothermal synthesis, magnetic, electrochemical, and electrocatalytic properties, Chem. -Eur. J. 16, 12000 – 12007 (2010). IF=5.69665. L. Q. Wang, V. Bambagioni, M. Bevilacqua, C. Bianchini, J. Filippi, A. Lavacchi, A. Marchionni, F. Vizza, X. Fang, P. K. Shen, Sodium borohydride as an additive to enhance the performance of direct ethanol fuel cells, J. Power Sources, 195, 8036-8043 (2010). IF=5.21166. V. Bambagioni, M. Bevilacqua, C. Bianchini, J. Filippi, A. Lavacchi, A. Marchionni, F. Vizza, P.K. Shen, Self-sustainable production of hydrogen, chemicals, and energy from renewable alcohols by electrocatalysis, ChemSusChem, 3, 851-855 (2010). IF=7.11767. Z. X. Yan, Z. F. Hu, C. Chen, H. Meng, P.K. Shen, H. B. Ji, Y. Z. Meng, Hollow carbon hemispheres supported palladium electrocatalyst at improved performance for alcohol oxidation, J. Power Sources 195, 7146–7151 (2010). IF=5.21168. L. Tian, H. L. Zou, J. X. Fu, X. F. Yang, Y. Wang, H. L. Guo, X. H. Fu, C. L. Liang, M. M. Wu, P.K. Shen, Q. M. Gao, Topotactic conversion route to mesoporous quasi-single-crystalline Co3O4 nanobelts with optimizable electrochemical performance, Adv. Funct. Mater. 20, 617–623 (2010). IF=11.80569. S. Q. Song, S. B. Yin, Z. H. Li, P. K. Shen, R. W. Fu, D. C. Wu, Effect of pore diameter of wormhole like mesoporous carbon supports on the activity of Pt nanoparticles towards hydrogen electrooxidation, J. Power Sources 195, 1946-1949 (2010). IF=5.21170. X. Fang, L. Q. Wang, P. K. Shen, G. F. Cui, C. Bianchini, An in situ Fourier transform infrared spectroelectrochemical study on ethanol electrooxidation on Pd in alkaline solution, J. Power Sources 195, 1375-1378 (2010). IF=5.211
zz
zl
ryyhj
zsxx":null}},