![孫克寧[哈爾濱工業大學理學院研究員]](/img/9/5a0/nBnauM3XzMTO1cjN5UTM1kTO0UTMyITNykTO0EDMwAjMwUzL1EzL1UzLt92YucmbvRWdo5Cd0FmLwE2LvoDc0RHa.jpg "孫克寧[哈爾濱工業大學理學院研究員]")
人物履歷
1981.9-1985.7 哈工大套用化學系,電化學工程專業,獲學士學位;
1985.9 -1988.6 哈工大套用化學系,套用電化學專業,獲碩士學位;
1992.9 -1996.10 哈工大金屬材料系,金屬材料專業,獲博士學位;
1996.10-1997.11 法國巴黎居里大學(巴黎六大)表面化學國家實驗室,博士後進修。
1990-1995年 哈爾濱工業大學套用化學系講師
1995-2002年 哈爾濱工業大學科學與工程研究院副研究員
2002-2008年 哈爾濱工業大學理學院研究員,博士生導師
2008-2009 哈爾濱工業大學化工學院,哈爾濱工業大學科學技術研究院化學與能源材料研究所,教授,博士生導師。美國電化學協會會員。
2009年至今,北京理工大學化工與環境學院院長,教授,博士生導師。
2014年至今,哈爾濱工業大學基礎與交叉科學研究院院長 ,教授,博士生導師。
學科
套用化學
研究方向
1、電化學研究方向:(1)表面處理,防腐和特種表面材料,主要是解決鋼鐵的腐蝕問題和表面改性問題,提高使用壽命,增加特種功能。(2)二次電池電極材料研究合成,主要研究鎳氫電池、鋰電池的電極材料和電極性能,改善電池性能,降低電池成本。同時開發研究新型電池材料以替代現有材料。(3)電化學超級電容器,研究儲能電極材料,改善性能,使之實用性進一步提高。(4)固體氧化物燃料電池電極材料和電池系統SOFC,研究合成中溫和低溫電極材料。2、催化材料和催化劑,以及合成材料工藝:(1)催化電極材料,研究電化學合成和電化學選擇催化。開發電化學催化的新研究方向。(2)催化合成精細化工品,如採油用的各種助劑,驅油劑,緩蝕劑合表面活性劑等;汽車三元催化劑和載體催化劑,解決汽車環保問題。(3)分子篩和其載體催化劑的研製和核磁共振研究。
論著成果1
[1]Sun kening, Zhang Yongzhong “Structure and Properties Electroless Ni Deposits” J.Mater. Sci.Technol. Vol.12, 1996:342-346 SCI, EI收錄
[2]Sun kening, HuXinguo “Electrodeposited Cr-Al2O3 composite coating for wear
resistance” Wear 196,1996:295-297 SCI, EI收錄
[3]Zhang Yongzhong, Sun Kening “Characterization of electroless Ni-P-PTFE composite deposits” J.of Materials Sci. Letter. 17,1998:119-122 SCI, EI收錄
[4]孫克寧 “中孔分子篩MCM-41的合成及Xe129核磁共振的研究” 無機化學學報,vol.16,(1), 2000: 115-118 SCI收錄
[5]K.Sun, M.A.Springuel-Huet, J.Frassard “On the roughness of the internal surface of MCM-41 materials studied by 129Xe NMR” Microporous and Mesoporous Materials, ELSEVIER, 33, 1999: 89-95 SCI收錄
[6]孫克寧“Si-Al/MCM-41分子篩的合成及Pt(NH3)4離子交換”,哈工大學報,2001,33(6) EI收錄
[7]曹瑩,孫克寧,“β-Ni(OH)2納米粉製備方法的改進”,高技術通訊,2002,5 EI
[8]曹瑩,孫克寧,“新型雷達波吸收塗層”,材料保護,2002, (6) EI
[9]孫克寧,“熱浸鍍鋁層結構研究”,材料科學與工藝, 2002, (3) EI
[10] 孫克寧,“MCM-48分子篩的合成、XRD的表征及129Xe核磁共振的研究”.哈爾濱工業大學學報,2002, 34(2) EI
論著成果2
Runwei Mo, David Rooney, Kening Sun* etc. 3D nitrogen-doped grapheme foam with encapsulated germanium/nitrogen doped grapheme yolk-shell nanoarchitecture for high-performance. Nature communication 13949(2017), doi:10.1038/ncomms13949
Hao, X.; Zhu, J.; Jiang, X.; Wu, H.; Qiao J.; Sun W.; Wang Z.; Sun K*. Ultrastrong Polyoxyzole Nanofiber Membranes for Dendrite-Proof and Heat-Resistant Battery Separators. Nano Letters 2016, 16 (5), 2981–2987. IF=13.779
Mo R., Tung S, Lei Z.,Zhao G., Sun K.*, Kotov N. 3D Layer-by-Layer-Assembled Composites for Cathodeswith 160 C Discharge Rates. ACS Nano, 2015, 5(9), 5009-5017. IF=13.334
Mo, R.; Lei, Z.; Sun, K.*; Rooney, D., Facile Synthesis of Anatase TiO2 Quantum- Dot/GrapheneNanosheet Composites with Enhanced Electrochemical Performance for Lithium-Ion Batteries. Advanced Materials 2014, 26 (13), 2084-2088. IF=18.96
Yang, Z.-Y.; Jin, L.-J.; Lu, G.-Q.; Xiao, Q.-Q.; Zhang, Y.-X.; Jing, L.; Zhang, X.-X.; Yan, Y.-M.; Sun, K. -N*., Sponge-Templated Preparation of High Surface Area Graphene with Ultrahigh Capacitive Deionization Performance. Advanced Functional Materials 2014, 24 (25), 3917-3925. IF=10.439
Li, B.; Cheng, Z.; Zhang, N.; Sun, K.*, Self-supported, binder-free 3D hierarchical iron fluoride flower-like array as high power cathode material for lithium batteries. Nano Energy 2014, 4, 7-13. IF=10.211
Zhao, G.; Mo, R.; Wang, B.; Zhang, L.; Sun, K.*, Enhanced Cyclability of LiO Batteries Based on TiO Supported Cathodes with No Carbon or Binder. Chemistry of Materials 2014, 26 (8), 2551-2556. IF=8.535
Li, B.; Zhang, N.; Sun, K.*, Confined Iron Fluoride@CMK-3 Nanocomposite as an Ultrahigh Rate Capability Cathode for Li-Ion Batteries. Small 2014, 10 (10), 2039-2046. IF=7.514
Shao L.; Wang Q; Fan L.; Wang P.; Zhang N; Sun K.*. Copper cobalt spinel as a high performance cathode for intermediate temperature solid oxide fuel cells.Chemical Communications2016,52, 8615-8618. IF=6.567
Mo R; Zhang F; Du Y; Lei Z; Rooney D.; Sun K*. Sandwich nanoarchitecture of LiV3O8/graphene multilayer nanomembranes via layer-by-layer self-assembly for long-cycle-life lithium-ion battery cathodes.Journal of Materials Chemistry A2015,3, 13717-13723. IF=8.262
1.Runwei Mo, David Rooney, Kening Sun* etc. 3D nitrogen-doped grapheme foam with encapsulated germanium/nitrogen doped grapheme yolk-shell nanoarchitecture for high-performance. Nature communication 13949(2017), doi:10.1038/ncomms13949
2.Hao, X.; Zhu, J.; Jiang, X.; Wu, H.; Qiao J.; Sun W.; Wang Z.; Sun K*. Ultrastrong Polyoxyzole Nanofiber Membranes for Dendrite-Proof and Heat-Resistant Battery Separators. Nano Letters 2016, 16 (5), 2981–2987. IF=13.779
3.Mo R., Tung S, Lei Z.,Zhao G., Sun K.*, Kotov N. 3D Layer-by-Layer-Assembled Composites for Cathodeswith 160 C Discharge Rates. ACS Nano, 2015, 5(9), 5009-5017. IF=13.334
4.Mo, R.; Lei, Z.; Sun, K.*; Rooney, D., Facile Synthesis of Anatase TiO2 Quantum- Dot/GrapheneNanosheet Composites with Enhanced Electrochemical Performance for Lithium-Ion Batteries. Advanced Materials 2014, 26 (13), 2084-2088. IF=18.96
5.Yang, Z.-Y.; Jin, L.-J.; Lu, G.-Q.; Xiao, Q.-Q.; Zhang, Y.-X.; Jing, L.; Zhang, X.-X.; Yan, Y.-M.; Sun, K. -N*., Sponge-Templated Preparation of High Surface Area Graphene with Ultrahigh Capacitive Deionization Performance. Advanced Functional Materials 2014, 24 (25), 3917-3925. IF=10.439
6.Li, B.; Cheng, Z.; Zhang, N.; Sun, K.*, Self-supported, binder-free 3D hierarchical iron fluoride flower-like array as high power cathode material for lithium batteries. Nano Energy 2014, 4, 7-13. IF=10.211
7.Zhao, G.; Mo, R.; Wang, B.; Zhang, L.; Sun, K.*, Enhanced Cyclability of LiO Batteries Based on TiO Supported Cathodes with No Carbon or Binder. Chemistry of Materials 2014, 26 (8), 2551-2556. IF=8.535
8.Li, B.; Zhang, N.; Sun, K.*, Confined Iron Fluoride@CMK-3 Nanocomposite as an Ultrahigh Rate Capability Cathode for Li-Ion Batteries. Small 2014, 10 (10), 2039-2046. IF=7.514
9.Shao L.; Wang Q; Fan L.; Wang P.; Zhang N; Sun K.*. Copper cobalt spinel as a high performance cathode for intermediate temperature solid oxide fuel cells.Chemical Communications2016,52, 8615-8618. IF=6.567
10.Mo R; Zhang F; Du Y; Lei Z; Rooney D.; Sun K*. Sandwich nanoarchitecture of LiV3O8/graphene multilayer nanomembranes via layer-by-layer self-assembly for long-cycle-life lithium-ion battery cathodes.Journal of Materials Chemistry A2015,3, 13717-13723. IF=8.262
