中文版 | ENGLISH
苏州大学成员

Dr. Xiaoqing Huang

发布时间:2019-01-09      浏览次数:12

  https://chemistry.suda.edu.cn/_upload/article/images/d5/b3/a2982d254f1ebb68616b7be6dcc7/8aeba9bc-cd87-45bd-8113-6ef868098123.jpg

姓名:黄小青
职称:教授、博士生导师
部门:化学学院
Email: hxq006@suda.edu.cn
课题组网站

学历及学术经历:

1984年出生于江西。20056月年毕业于西南师范大学(现在西南大学)化学化工学院,获学士学位;20119月毕业于厦门大学化学化工学院,获博士学位,导师为郑南峰和郑兰荪教授;20119月至20146月美国University of California, Los Angeles材料科学与工程系博士后,导师为著名材料科学家Yu HuangXiangfeng Duan教授。2014年受聘于苏州大学材化部,特聘教授,博士生导师。入选江苏省双创人才计划、江苏省六大人才高峰高层次人才、江苏省“333工程培养对象、苏州市高等院校、科研院所紧缺高层次人才金鸡湖双百人才计划等。现作为课题负责人主持或参与苏州大学人才引进科研启动费、江苏省杰出青年基金项目、国家自然科学基金面上项目、科技部纳米专项(两项)。

  

研究领域:

无机\有机纳米材料控制制备;多功能纳米材料;金属纳米催化剂;能源储存及转移;生物纳米材料。


第一通讯作者论文:

2017

1.  K.   Z. Jiang, D. D. Zhao, S. J. Guo*, X. Zhang, X. Zhu, J. Guo, G.   Lu, X. Q. Huang*, “Efficient oxygen reduction   catalysis by subnanometer Pt alloy nanowires” Science   Advances 2017, 3(2), e1601705;

2.  P.   T. Wang=, X. Zhang=, J. Zhang, S. Wan, S. J. Guo*,   G. Lu*, J. L. Yao, X. Q. Huang*, “Precise   tuning in platinum-nickel/nickel sulfide interface nanowires for synergistic   hydrogen evolution catalysis” Nat. Commun. 2017, 8,   14580;

3.    L. Z. Bu, Q. Shao, Y. C. Pi, …. X. Q. Huang*,…. 2017,   Under revision;

4.    L. Z. Bu, Q. Shao, B. E, J. L. Yao, J. Guo, X. Q. Huang*, “PtPb/PtNi   Intermetallic Core/Atomic Layer Shell Octahedra for Efficient Oxygen   Reduction Electrocatalysis” JACS 2017, 139 (28),   pp 9576-9582;

5.  S. X. Bai, Q. Shao, P. T. Wang, Q. G. Dai, X. Y. Wang, X.   Q. Huang*, “Highly Active and Selective Hydrogenation of CO2 to Ethanol   by Ordered Pd-Cu Nanoparticles” JACS 2017, 139   (20), 6827-6830;

6.  Y.   C. Pi, Q. Shao, P. T. Wang, F. Lv, S. J. Guo*, J. Guo, X.   Q. Huang*, “Trimetallic Oxyhydroxide Coralloids for Efficient   Oxygen Evolution Electrocatalysis” Angew. Chem. Int. Ed. 2017,   56(16), 4502-4506;

7.  F.   L. Li, Q. Shao, X. Q. Huang*, J. P. Lang*, “Nanoscale   Trimetallic Metal-Organic Frameworks Enable Efficient Oxygen Evolution   Electrocatalysis” Angew. Chem. Int. Ed. 2017, DOI:   10.1002/anie.201711376;

8.  N.   Zhang, Y. G. Feng, X. Zhu, S. J. Guo, J. Guo, X. Q. Huang*,   “Superior bifunctional liquid fuel oxidation and oxygen reduction   electrocatalysis enabled by PtNiPd core-shell nanowires” Adv.   Mater.2017, 29(7), DOI: 10.1002/adma.201603774;

9.  Y. G. Feng, Q. Shao, X.   N. Cui, ….X. Q. Huang*,…. 2017, Under revision;

10.  Y.   C. Pi, Q. Shao, P. T. Wang, J. Guo, X. Q. Huang*,   “General Formation of Monodisperse IrM (M=Ni, Co, Fe) Bimetallic Nanoclusters   as Bifunctional Electrocatalysts for Acidic Overall Water Splitting” Adv.   Funct. Mater. 2017, In Press;

11.  K. Z. Jiang, Q. Shao, D. D. Zhao, L. Z. Bu, J. Guo, X. Q.   Huang*, “Phase and Composition Tuning of One-Dimensional   Platinum-Nickel Nanostructures for Highly Efficient Electrocatalysis” Adv.   Funct. Mater. 2017, In Press;

12.  P. T. Wang,# Q. Shao,# X. N. Cui,   X. Zhu, X. Q. Huang*, “Hydroxide membranes coated Pt3Ni   nanowires as highly efficient catalysts for selective hydrogenation   reaction” Adv. Funct. Mater. 2017, In Press;

13.  N.   Zhang, Q. Shao, Y. C. Pi, J. Guo, X. Q. Huang*Chem.   Mater.2017, In Press;

14.  S. X. Bai, Q. Shao, Y. G. Feng, L. Z. Bu, X. Q. Huang*, “Highly   Efficient Carbon Dioxide Hydrogenation to Methanol Catalyzed by Zigzag   Platinum-Cobalt Nanowires”Small 2017, In Press;

15.  Y. Zhang, Q. Shao, Y. C. Pi, J. Guo, X. Q. Huang*, “A   Cost-efficient Bifunctional Ultrathin Nanosheets Array for Electrochemical   Overall Water Splitting”Small 2017, In Press;

16.    M. W. Zhu, Q. Shao, Y. C. Pi, B. Huang, Y. Qian*, J. Guo, X. Q.   Huang*, “Ultrathin Vein-Like Iridium-Tin Nanowires with Abundant   Oxidized Tin as High-Performance Ethanol Oxidation Electrocatalysts” Small 2017, In   Press;

17.  X. H. Sun, Q. Shao, Y. C. Pi, J. Guo, X. Q. Huang*, “A   General Approach to Ultrathin NiM (M = Fe, Co, Mn) Hydroxide Nanosheets as   High-Performance Low-Cost Electrocatalysts for Overall Water Splitting”JMCA 2017, 5,   7769-7775;

18.    N. Zhang, Y. Zhu, Q. Shao, X. Zhu, X. Q. Huang*, “Ternary   PtNi/PtxPb/Pt core/multishell nanowires as efficient and stable   electrocatalysts for fuel cell reactions” JMCA 2017, 5,   18977-18983;

19.    P. P. Song, X. N. Cui, Q. Shao, Y. G. Feng, X. Zhu, X. Q. Huang*,   “Networked Pt-Sn nanowires as efficient catalysts toward alcohol   electrooxidation” JMCA 2017, TA-COM-09-2017-008467.R1;

20.    D. D. Zhao=, K. Z. Jiang=, Y. C. Pi, X. Q.   Huang*, “Superior electrochemical oxygen evolution enabled by   three-dimensional layered double hydroxide nanosheet superstructures” ChemCatChem 2017,   9(1), 84-88;

21. Y.   Tang, T. Yang, Q. Wang, X. Lv, X. Song, H. Ke, Z. Guo, X. Q. Huang,   J. Hu, Z. Li, P. Yang*, X. Yang*, H. Chen*, “Albumin-coordinated assembly of   clearable platinum nanodots for photo-induced cancer theranostics” Biomaterials 2017,   DOI: 10.1016/j.biomaterials.2017.10.030;

  

  

2016

22.  L.   Z. Bu, N. Zhang, S. J. Guo*, X. Zhang, J. Li, J. L. Yao, T. Wu, G.   Lu, J. Y. Ma, D. Su*X. Q. Huang*,   “Biaxially strained PtPb/Pt core/shell nanoplate boosts oxygen reduction   catalysis” Science2016, 354(6318), 1410-1414;

23.     L. Z. Bu, S. J. Guo*, X. Zhang, X. Shen, D. Su, G. Lu, X. Zhu, J.   L. Yao, J. Guo, X. Q. Huang*, “Surface engineering of   hierarchical platinum-cobalt nanowires for efficient electrocatalysis” Nat.   Commun.2016, 7, 11850;

24.  P.   T. Wang, K. Z. Jiang, G. M. Wang, J. L. Yao, X. Q. Huang*,   “Phase and interface engineering of platinum-nickel nanowires for efficient   electrochemical hydrogen evolution” Angew. Chem. Int. Ed.2016,   55(41), 12859-12863;

25.  K.   Z. Jiang=, P. T. Wang=, S. J. Guo*,   X. Zhang, X. Shen, G. Lu, D. Su, X. Q. Huang*,   “Ordered PdCu-based nanoparticles as bifunctional oxygen-reduction and   ethanol-oxidation electrocatalysts” Angew. Chem. Int. Ed.2016,   55(31), 9030-9035;

26.  Y. C. Pi, N. Zhang, S. J. Guo*, J. Guo, X. Q.   Huang*, “Ultrathin laminar Ir superstructure as highly   efficient oxygen evolution electrocatalyst in broad pH range” Nano   Lett. 2016, 16(7), 4424-4430;

27.  J.   B. Ding, L. Z. Bu, S. J. Guo, Z. P. Zhao, E. B. Zhu, Y. Huang*X.   Q. Huang*, “Morphology and phase controlled construction of   Pt-Ni nanostructures for efficient Electrocatalysis” Nano Lett.2016,   16(4), 2762-2767;

28.    N. Zhang, L. Z. Bu, S. J. Guo*, J. Guo, X. Q. Huang*,   “Screw thread-like platinum-copper nanowires bounded with high-index facets   for efficient electrocatalysis” Nano Lett.2016, 16 (8),   5037-5043;

29.    J. B. Ding, Y. Zhou, Y. G. Li*, S. J. Guo*X.   Q. Huang*, “MoS2 nanosheet assembling   superstructure with a three-dimensional ion accessible site: a new class of   bifunctional materials for batteries and electrocatalysis” Chem.   Mater. 2016, 28(7), 2074-2080;

30.    N. Zhang, S. J. Guo*, X. Zhu, J. Guo, X. Q. Huang*,   “Hierarchical Pt/PtxPb core/shell nanowires as efficient catalysts   for electrooxidation of liquid fuels” Chem. Mater. 2016,   28(12), 4447-4452;

31.    Y. Zhang, L. Z. Bu, K. Z. Jiang, S. J. Guo*X. Q. Huang*,   “Concave Pd-Pt core-shell nanocrystals with ultrathin Pt shell feature and   enhanced catalytic performance” Small2016, 12(6), 706-712;

32.    Y. G. Feng, L. Z. Bu, S. J. Guo, J. Guo, X. Q. Huang*,   “3D Platinum-lead nanowire networks as highly efficient ethylene glycol   oxidation electrocatalysts” Small2016, 12(33), 4464-4470;

33.    Y. Zhang, X. Zhu, J. Guo, X. Q. Huang*, “Controlling   palladium nanocrystals by solvent-induced strategy for efficient multiple   liquid fuels electrooxidation” ACS Appl. Mater. Interfaces 2016,   8(32), 20642-20649;

34.    L. Z. Bu, Y. G. Feng, J. L. Yao*, S. J. Guo, J. Guo, X. Q.   Huang*, “Facet and dimensionality control of Pt nanostructures   for efficient oxygen reduction and methanol oxidation electrocatalysts” Nano   Res.2016, 9(9), 2811-2821;

35    X. H. Sun, N. Zhang, X. Q. Huang*, “Polyaniline-coated   platinum nanocube assemblies as enhanced methanol oxidation electrocatalysts” ChemCatChem2016,   8(22), 3436-3440;

36.    S. F. Xie, Q. C. Xu, X. Q. Huang*, “Defect-rich metal   nanocrystals in catalysis” ChemCatChem 2016, 8(3),   480-485;

  

2015

37.  L.   Z. Bu, J. B. Ding, S. J. Guo*, X. Zhang, D. Su, X. Zhu, J.   L. Yao, J. Guo, G. Lu, X. Q. Huang*, “A general method   for multimetallic platinum alloy nanowires as highly active and stable oxygen   reduction catalysts” Adv. Mater.2015, 27(44), 7204-7212;

38.  Y.   Zhang, M. S. Wang, E. B. Zhu, Y. B. Zheng, Y. Huang*X.   Q. Huang*, “Seedless growth of palladium nanocrystals with   tunable structures: from tetrahedra to nanosheets” Nano Lett.2015, 15(11),   7519-7525;

39.  X.   H. Sun, K. Z. Jiang, N. Zhang, S. J. Guo*, X. Q. Huang*,   “Crystalline control of {111} bounded Pt3Cu nanocrystals:   multiply-twinned Pt3Cu icosahedra with enhanced electrocatalytic   properties” ACS Nano2015, 9(7), 7634-7640;

40.    X. H. Sun, X. Zhu, N. Zhang, J. Guo, S. J. Guo, X. Q. Huang*,   “Controlling and self assembling of monodisperse platinum nanocubes as   efficient methanol oxidation electrocatalysts” Chem. Commun.2015,   51(17), 3529-3532;

41.    J. B. Ding, X. Zhu, L. Z. Bu, J. L. Yao, J. Guo, S. J. Guo*X.   Q. Huang*, “Highly open rhombic dodecahedral PtCu   nanoframes” Chem. Commun.2015, 51(47), 9722-9725;

42.    J. B. Ding, L. Z. Bu, N. Zhang, J. L. Yao, Y. Huang, X. Q. Huang*,   “Facile synthesis of ultrathin bimetallic PtSn wavy nanowires by nanoparticle   attachment as enhanced hydrogenation catalysts” Chem. Eur.   J. 2015, 21(10), 3901-3905;

43.    K. Z. Jiang, L. Z. Bu, P. T. Wang, S. J. Guo*X. Q. Huang*,   “Trimetallic PtSnRh wavy nanowires as efficient nanoelectrocatalysts for   alcohol electrooxidation” ACS Appl. Mater. Interfaces2015,   7(27), 15061-15067;

  

第一作者论文:

44. X.   Huang, Y. Huang,* et al. Science, 2015, 348, 1230.

45. X.   Huang, Y. Huang,* et al. Nano. Lett., 2014, 12, 4265.

46. X.   Huang, Y. Huang,* et al. Energy Environ. Sci., 2014, 7,   2957.

47. X.   Huang, Y. Huang,* et al. Angew. Chem. Intl. Ed., 2013, 52,   2520.

48. X.   Huang, Y. Huang,* et al. Angew. Chem. Intl. Ed., 2013, 52,   6063.

49. X.   Huang, Y. Huang,* et al. Adv. Mater., 2013, 25, 2974.

50. X.   Huang, Y. Huang,* et al. Nanoscale, 2013, 5, 6284.

51. X.   Huang, Y. Huang,* et al.JMCA, 2013, 1,14449.

52. X.   Huang, Y. Huang,* et al. Nano Lett., 2012, 12, 4265.

53. X.   Huang, Y. Huang,* et al. Chem.-Eur. J, 2012, 18, 9505.

54. X.   Huang, N. Zheng,* et al. Nat. Nanotechol., 2011, 6, 28.

55. X.   Huang, N. Zheng,* et al. J. Am. Chem. Soc., 2011, 13,   4718.

56. X.   Huang, N. Zheng,* et al. J. Am. Chem. Soc., 2011, 13,   15946.

57. X.   Huang, N. Zheng,* et al. Adv. Mater., 2011, 23, 3420.

58. S.   Tang,# X. Huang,# Nanfeng Zheng,* et   al. Adv. Funct. Mater., 2010, 20, 2442.

59. X.   Huang, N. Zheng,* et al. J. Am. Chem. Soc., 2009, 39,   13916.

60. X.   Huang, N. Zheng,* J. Am. Chem. Soc., 2009, 13, 4602.

61. X.   Huang, N. Zheng,* et al. Angew. Chem. Int. Ed., 2009, 48,   4808.

62. X.   Huang, N. Zheng,* et al. Small, 2009, 3, 361.

  


打印】 【关闭】 【返回
苏州大学-西安大略大学同步辐射联合研究中心
版权所有