教授,中南大學“升華學者”,中國微米納米學會理事。2004年中南大學材料物理博士畢業,2009-2010年為香港城市大學物理與材料系研究員(Research Fellow)。
基本介紹
- 中文名:齊衛宏
- 畢業院校:中南大學“
- 主要成就:2009-2010年為香港城市大學物理與材料系研究員
- 職務:中國微米納米學會理事
簡介,研究方向,主要經歷,人才計畫,主要獲獎,學術任職,人才培養,部分發表的論文,
簡介
主要從事納米材料的結構與相變、計算材料學的研究。在Small等刊物上發表學術論文84篇,SCI收錄53篇,EI收錄55篇, 論文被他引461次,H因子為13。入選教育部新世紀優秀人才支持計畫、湖南省青年骨幹教師、湖南省高校科技創新團隊骨幹成員、中南大學首批升華育英人才計畫。曾獲湖南省優秀博士論文獎、湖南省優秀自然科學論文一等獎,中南大學黃培雲教育獎等。主持國家自然科學基金、湖南省自然科學基金(重點)及中國博士後科學基金(特別資助)等科研項目。擔任國際SCI刊物《Journal of Nanomaterials》客座主編(Lead Guest Editor)、國際刊物《World Journal of Nano Science and Engineering》、《OpenJournal o Microphysics》、《Open Journal of Metal》編委,被邀請為J Am Chem Soc等20種SCI刊物審稿人。
研究方向
納米固體的結構與相變納米固體的尺寸效應石墨烯的製備與表征材料的原子尺度模擬
主要經歷
2009年-2010年,香港城市大學,研究員(Research Fellow)2007年-2009年,中南大學,冶金物理與化學博士後2001年-2004年,中南大學,材料物理與化學博士
人才計畫
中南大學“升華學者”特聘教授(2011)教育部新世紀優秀人才支持計畫(2008)湖南省青年骨幹教師(2009)湖南省高校科技創新團隊骨幹成員(2010)中南大學首批“育英計畫”入選者(1999)
主要獲獎
湖南省優秀博士論文(2006)湖南省優秀自然科學論文一等獎(第1)(2008)中國博士後科學基金特別資助(2009)中國博士科學基金一等資助(2008)中南大學黃培雲教育獎(2008)
學術任職
中國微米納米學會理事《Journal of Nanomaterials》客座主編(Lead Guest Editor)《World Journal of Nano Science and Engineering》編委《Open Journal of Microphysics》編委《Open Journal of Metals》編委JACS、JPCC等20種SCI刊物審稿人
人才培養
李業軍,2008-2010,碩士,發表SCI論文5篇,獲海亮獎學金,畢業論文被評為中南大學優秀碩士論文,並已被推薦參評湖南省優秀碩士論文評選。現在比利時魯汶大學攻讀博士學位。熊世雲,2009-2011,碩士,發表SCI論文8篇,獲李薰獎學金、寶鋼獎學金、校首屆優秀畢業研究生學術一等獎。現在法國巴黎中央理工學院攻讀博士學位。
部分發表的論文
[1] W. H. Qi, Y. J. Li, S. Y. Xiong, S. T. Lee,Modeling Size and Shape Effects on the Order-Disorder Phase-Transition Temperature of CoPt Nanoparticles,
Small 6(2010) 1996–1999
[2] W. H. Qi, S. T. Lee, Phase stability, Melting and Alloy formation of Au-Ag Bimetallic Nanoparticles,
Journal of Physical Chemistry C 114(2010) 9580–9587
[3] S. Y. Xiong, W. H. Qi *, B. Y. Huang, M. P. Wang, L. Y. Wei, Gibbs Free Energy and Size-Temperature Phase Diagram of Hafnium Nanoparticles
Journal of Physical Chemistry C , 115(2011)10365
[4] S. Y. Xiong, W. H. Qi *, B. Y. Huang, M. P. Wang,, Z. Li, S. Q. Liang.Size-Temperature Phase Diagram of Titanium Nanosolids
Journal of Physical Chemistry C , (2011)
[5] W. H. Qi*, M. P. Wang, Comment on “Stability of Scanning Tunneling Microscopy Tip-Induced Bilmetallic Nanoclusters",
Journal of Physical Chemistry B, 109 ( 2005) 22078-22079
[6] S. Y. Xiong, W. H. Qi *, Y. J. Cheng, B. Y. Huang, M. P. Wang. Y. J. Li, Modeling size effect on surface free energy of metallic nanoparticles and nanocavities
Physical Chemistry Chemical Physics,13(2011)10648-10651
[7] S. Y. Xiong, W. H. Qi*, Y. J. Cheng, B. Y. Huang, M. P. Wang. Y. J. Li, Universal relation for size dependent thermodynamic properties of metallic nanoparticle
Physical Chemistry Chemical Physics, 13(2011)10652-10660
[8] S. Y. Xiong, W. H. Qi *, B. Y. Huang, M. P. Wang, Size, Shape and Composition Dependent Alloying Ability of Bimetallic Nanoparticles
ChemPhysChem, 12 (2011) 1317-1324
[9] W. H. Qi*, B. Y. Huang, M. P. Wang et al. Molecular dynamic simulation of the size and shape dependent lattice parameter of small Platinum nanoparticles,
Journal of Nanoparticle Research, 11(2009) 575–580
[10] W. H. Qi*, M. P. Wang, Size and shape dependent lattice parameters of metallic nanoparticles,
Journal of Nanoparticle Research, 7 (2005) 51–57
[11] S. Y. Xiong, W. H. Qi*, B. Y. Huang, M. P. Wang. Y. J. Li, Z. Li and S. Q. Liang, Size and temperature induced phase transformations of titanium nanoparticles
EPL, 93(2011) 66002 (IF=2.753)
[12] W. H. Qi*, B. Y. Huang, M. P. Wang. Structure of unsupported small Palladium nanoparticles,
Nanoscale Research Letters 4(2009) 269–273
[13] W. H. Qi*, M. P. Wang, Size and shape dependent melting temperature of metallic nanoparticles,
Materials Chemistry and Physics 88(2004)280-284
[14] S. Y. Xiong, W. H. Qi*, B. Y. Huang, M. P. Wang, Y. J. Li, Size and Shape Dependent Gibbs Free Eenergy and Phase Stability of Titanium and Zirconium Nanoparticles.
Materials Chemistry and Physics 120 (2010) 446–451
[15] D. Xie, M. P. Wang,W. H. Qiand L. F. Cao. Thermal stability of indium nanocrystals: A theoretical study,
Materials Chemistry and Physics.96(2006)418–421
[16] D. Xie, M. P. Wang, W. H. Qi, A simplified model to calculate the surface-to-volume atomic ratio dependent cohesive energy of nanocrystals.
Journal of Physics: Condensed Matter16 (2004) L401–L405.
[17] W. H. Qi, S. T. Lee, Core-shell Structures of Silicon nanoparticles and nanowires with free and hydrogenated surface,
Chemical Physics Letters 483 (2009) 247–249
[18] W. H. Qi*,M. P. Wang, G. Y. Xu, The partical size dependence of cohesive energy of metallic nanoparticles,
Chemical Physics Letters 372 (2003) 632-634.
[19] W. H. Qi*, Comment on "The cluster size dependence of thermal stabilities of both molybdenum and tungsten nanoclusters "
Chemical Physics Letters402 (2005) 279-281.
[20] W. H. Qi*,M. P. Wang,Structural evolution of Pd-79 cluster before melting,
Materials Letters 61 (2007) 3064–3067
[21] W. H. Qi*, Modeling the Relaxed Cohesive Energy of Metallic Nanoclusters,
Materials Letters ,60(2006)1678-1681
[22] W. H. Qi*,M. P. Wang, Size and shape dependent superheating of nanoparticles embedded in a matrix,
Materials Letters 59 (2005) 2262– 2266.
[23] W. H. Qi*, M. P. Wang, W. Y. Hu, Calculate the cohesive energy of the metallic nanoparticles by Lennard-Jones potential,
Materials Letters, 58(2004)1745-1749
[24] W. H. Qi*,M. P. Wang, M. Zhou, W. Y. Hu. Surface-Area-Difference model for thermodynamic properties of metallic nanocrystals,
Journal of Physics D: Applied Physics 38 (2005) 1429-1436
[25] Y. J. Li, W. H. Qi*, B. Y. Huang, M. P. Wang, J. F. Liu, S. Y. Xiong. Generalized Bragg-Williams model for the size dependent order-disorder transition of bimetallic nanoparticles
Journal of Physics D: Applied Physics ,44 (2011) 115405