基本信息
褚卫国 男 博导 国家纳米科学中心
电子邮件: wgchu@nanoctr.cn
通信地址: 北京中关村北一条11号
邮政编码: 100190
电子邮件: wgchu@nanoctr.cn
通信地址: 北京中关村北一条11号
邮政编码: 100190
招生信息
招生专业
070205-凝聚态物理080502-材料学
招生方向
纳米能源材料,纳米加工与器件
教育背景
1997-03--2000-05 哈尔滨工业大学 博士1993-09--1996-01 哈尔滨工业大学 硕士
工作经历
工作简历
2012-04~现在, 国家纳米科学中心, 研究员2004-03~2012-03,国家纳米科学中心, 副研2001-12~2004-03,东京大学/东京理科大学, Research associate2000-05~2001-12,中科院物理所, 博士后1996-07~1997-03,合肥工业大学, 助研
社会兼职
2015-01-01-今,Surface Topography:measurment and Properties, Editor
专利与奖励
奖励信息
(1) 北京市科技进步一等奖, 一等奖, 市地级, 2004
专利成果
[1] 乔治, 陈佩佩, 胡海峰, 田毅, 周一轩, 胡俊言, 褚卫国. 一种传感芯片及其制备方法. CN2023102946197, 2023-03-23.[2] 陈佩佩, 褚卫国, 田毅, 胡海峰, 闫兰琴. 一种金属和介质复合的纳米图案化基底及其制备方法与应用. CN202310045116.6, 2023-01-30.[3] 褚卫国, 赵庭乔. 一种三维石墨化多孔碳材料及其制备方法和用途. CN: CN111285347B, 2022-03-22.[4] 王文涛, 董凤良, 褚卫国. 基于偏振态调控实现超透镜变焦的装置、变焦方法和应用. CN: CN111338156B, 2022-02-18.[5] 陈佩佩, 褚卫国, 胡海峰, 田毅. 一种表面增强拉曼散射芯片及其制备方法与应用. CN202111644034.0, 2021-12-29.[6] 陈佩佩, 褚卫国, 田毅, 胡海峰. 一种介质增强拉曼散射芯片及其制备方法与应用. CN2021116409761.1, 2021-12-29.[7] 宋志伟, 褚卫国, 徐丽华, 闫兰琴. 一种低温制备非晶硅膜材料的方法、得到的产品和用途. CN: CN111139452B, 2021-10-26.[8] 宋志伟, 褚卫国. 一种在大面积衬底上磁控溅射制备薄膜的方法. CN: CN111139439B, 2021-09-28.[9] 徐丽华, 褚卫国, 陈佩佩, 闫兰琴. 一种硅表面制作密度可调的锥状陷光结构的方法及制得的黑硅. CN: CN110783417B, 2021-06-29.[10] 徐陶然, 陈佩佩, 胡海峰, 田毅, 黄辉, 褚卫国. 一种电学-光谱信号检测装置、系统装置及检测方法. CN: CN113030062A, 2021-06-25.[11] 赵乐, 褚卫国, 董凤良, 陈佩佩, 闫兰琴, 田毅, 宋志伟, 徐丽华, 胡海峰. 一种利用光谱椭偏仪检测超薄金属膜的方法及装置. CN: CN112964647A, 2021-06-15.[12] 陈佩佩, 褚卫国, 田毅, 黄辉, 徐丽华, 徐陶然. 一种纳米压印模板及其制备方法和应用. CN: CN112305859A, 2021-02-02.[13] 胡海峰, 褚卫国, 陈佩佩, 董凤良, 闫兰琴. 一种精度为亚十纳米的电子束曝光和定位方法. CN: CN112051713A, 2020-12-08.[14] 褚卫国, 谭兴华. 一种水系锂离子电池正极材料及其制备方法和用途. CN: CN111525123A, 2020-08-11.[15] 王汉夫, 褚卫国, 郭延军, 李晓军, 徐波, 王东伟, 熊玉峰. 一种薄膜面内热导率的测量装置及方法. CN: CN111458369A, 2020-07-28.[16] 闫兰琴, 褚卫国, 徐丽华, 赵乐. 一种氮化铝薄膜及其制备方法和用途. CN: CN111364017A, 2020-07-03.[17] 褚卫国, 赵庭乔. 一种S元素和P元素双掺杂的多孔碳、其制备方法及应用. CN: CN111224100A, 2020-06-02.[18] 宋志伟, 褚卫国, 徐丽华, 闫兰琴. 一种低温制备多晶硅膜材料的方法、得到的产品和用途. CN: CN111155070A, 2020-05-15.[19] 胡海峰, 褚卫国, 董凤良, 闫兰琴, 陈佩佩. 一种亚10纳米间隙结构的制备方法及其应用. CN: CN110993487A, 2020-04-10.[20] 胡海峰, 褚卫国, 陈佩佩, 董凤良, 闫兰琴. 一种亚10纳米库仑阻塞器件的制备方法. CN: CN110854020A, 2020-02-28.[21] 陈佩佩, 褚卫国, 田毅, 闫兰琴. 一种表面增强拉曼衬底的制备方法. CN: CN106770180B, 2019-10-11.[22] 褚卫国, 郭利民, 王汉夫. 一种高镍富锂正极材料、及其制备方法和用途. CN: CN109921007A, 2019-06-21.[23] 褚卫国, 刘圣男, 王汉夫. 一种三维微纳复合结构的石墨化碳材料、其制备方法及应用. CN: CN108767261A, 2018-11-06.[24] 陈佩佩, 董凤良, 褚卫国. 一种基于电子束曝光的光栅制作方法. CN: CN108398737A, 2018-08-14.[25] 闫兰琴, 褚卫国. 一种TiZn合金膜及其制备方法和用途. CN: CN108396290A, 2018-08-14.[26] 陈佩佩, 田毅, 闫兰琴, 褚卫国. 一种表面增强拉曼衬底及其制备方法. CN: CN108375567A, 2018-08-07.[27] 王汉夫, 褚卫国. 一种样品热导率和热电势的测量装置及方法. CN: CN108061738A, 2018-05-22.[28] 褚卫国, 刘海强, 张娟, 王汉夫. 一种P非等量取代Mn掺杂改性镍锰酸锂的方法及用途. CN: CN107611422A, 2018-01-19.[29] 褚卫国, 谭兴华, 张娟, 王汉夫. 一种锂离子电池正极材料及其制备方法. CN: CN107104233A, 2017-08-29.[30] 褚卫国, 蒋毅, 田瑞源, 王汉夫. 一种锂离子电池正极材料及其制备方法和应用. CN: CN107069034A, 2017-08-18.[31] 王汉夫, 杨方龙, 褚卫国. 热电材料性能参数测量装置及测量方法. CN: CN107037264A, 2017-08-11.[32] 褚卫国, 谭兴华, 张娟, 王汉夫. 一种三维网络结构材料、制备方法及其用途. CN: CN106972171A, 2017-07-21.[33] 闫兰琴, 褚卫国, 徐丽华, 宋志伟. 一种透明超疏水薄膜、其制备方法及用途. CN: CN106835043A, 2017-06-13.[34] 徐丽华, 褚卫国, 陈佩佩. 一种表面增强拉曼基底及其制备方法. CN: CN106770157A, 2017-05-31.[35] 贺涛, 王凯, 褚卫国, 张先锋. 用于纳米颗粒的光谱椭偏拟合方法. CN: CN106092861A, 2016-11-09.[36] 褚卫国, 蒋毅. 一种二维氮掺杂分级孔碳纳米片、制备方法及其在锂硫电池中的应用. CN: CN106025239A, 2016-10-12.[37] 贺涛, 王凯, 褚卫国, 张先锋. 一种确定薄膜连续性的临界厚度的方法. CN: CN106017338A, 2016-10-12.[38] 王汉夫, 杨方龙, 褚卫国. 微尺度样品的热电势测量电路、平台及方法. CN: CN105785102A, 2016-07-20.[39] 褚卫国, 刘海强, 王汉夫. 一种镍锰酸锂、其制备方法及用途. CN: CN105753072A, 2016-07-13.[40] 田毅, 张先锋, 闫兰琴, 宋志伟, 褚卫国. 一种采用光谱椭偏仪对金属膜进行检测的方法. CN: CN105674899A, 2016-06-15.[41] 徐丽华, 陈佩佩, 褚卫国. 一种变截面硅孔和硅通道的刻蚀方法. CN: CN105632916A, 2016-06-01.[42] 王汉夫, 褚卫国, 金灝, 熊玉峰. 一种热电性能测量样品台及热电性能测量装置. CN: CN105606643A, 2016-05-25.[43] 徐丽华, 李志琴, 董凤良, 陈佩佩, 褚卫国. 一种硅刻蚀方法. CN: CN105609416A, 2016-05-25.[44] 褚卫国, 郭利民, 王汉夫. 一种多孔硅酸铁锂、制备方法及其用途. CN: CN105406037A, 2016-03-16.[45] 徐丽华, 闫兰琴, 褚卫国. 一种利用光刻胶以及低温等离子刻蚀制备黑硅的方法. CN: CN105399045A, 2016-03-16.[46] 陈佩佩, 李志琴, 董凤良, 闫兰琴, 徐丽华, 褚卫国. 一种纳米结构阵列及其制备方法和用途. CN: CN105271103A, 2016-01-27.[47] 李晓军, 赵勇, 刘颖, 江鹏, 褚卫国, 赵修臣. 基于三维ZnO@MnO 2 复合纳米阵列叉指电极的超级电容器及其制备方法. 中国: CN104465119A, 2015.03.25.[48] 王汉夫, 李晓笑, 褚卫国, 金灏, 熊玉峰. 微测量电极的制作方法和热电势的测量方法及相关装置. CN: CN105203825A, 2015-12-30.[49] 闫兰琴, 褚卫国, 徐丽华, 张先锋. 一种氟化碳膜及其制备方法和用途. CN: CN105154850A, 2015-12-16.[50] 褚卫国, 陈建坤, 王汉夫. 一种镍锰酸锂正极材料、其制备方法和用途. CN: CN105161712A, 2015-12-16.[51] 褚卫国, 谭兴华, 王汉夫. 一种锰酸锂正极材料、制备方法及用途. CN: CN105161711A, 2015-12-16.[52] 赵珉, 褚卫国, 董凤良, 闫兰琴, 徐丽华. 一种石墨烯场效应晶体管及其制作方法. CN: CN105140284A, 2015-12-09.[53] 李晓军, 宋志伟, 褚卫国, 赵修臣, 刘颖. 一种多孔镍基碳纤维复合材料及其制备方法和用途. CN: CN105047420A, 2015-11-11.[54] 田瑞源, 褚卫国, 王汉夫. 一种高倍率LiFePO 4 /C正极材料及其制备方法. CN: CN104638261A, 2015-05-20.[55] 宋志伟, 褚卫国. 一种氮氧化硅膜材料及其制备方法和用途. CN: CN104532207A, 2015-04-22.[56] 李晓军, 赵勇, 刘颖, 褚卫国, 赵修臣. 一种多孔石墨烯-MnO 2 复合薄膜、其制备方法及其用途. CN: CN104538209A, 2015-04-22.[57] 宋志伟, 褚卫国. 一种超薄氮氧化硅膜材料及其制备方法和用途. CN: CN104498895A, 2015-04-08.[58] 董凤良, 徐丽华, 宋志伟, 闫兰琴, 亓丽梅, 褚卫国. 一种多波段太赫兹滤波器及其制作方法. CN: CN104505561A, 2015-04-08.[59] 董凤良, 徐丽华, 宋志伟, 闫兰琴, 褚卫国. 一种金属/柔性介质层/金属周期结构吸波材料及其制备方法. CN: CN104505598A, 2015-04-08.[60] 徐丽华, 宋志伟, 闫兰琴, 董凤良, 褚卫国. 一种金属铝膜纳米结构刻蚀方法. CN: CN104498949A, 2015-04-08.[61] 董凤良, 陈佩佩, 闫兰琴, 李志琴, 李志刚, 褚卫国. 一种基于金属纳米网格的透明电极及其制备方法. CN: CN104485279A, 2015-04-01.[62] 闫兰琴, 褚卫国. 一种兼具可见光近红外增透和特殊浸润性功能薄膜的物理制备方法. CN: CN104480434A, 2015-04-01.[63] 董凤良, 徐丽华, 宋志伟, 褚卫国. 一种微偏振片阵列及其制作方法. CN: CN104460021A, 2015-03-25.[64] 李晓军, 刘颖, 赵修臣, 褚卫国, 江鹏, 宋志伟. 一种磁控溅射制备纳米多孔金属薄膜的方法. CN: CN104451547A, 2015-03-25.[65] 徐丽华, 褚卫国. 一种低频BOSCH深硅刻蚀方法. CN: CN104465336A, 2015-03-25.[66] 李晓军, 赵勇, 江鹏, 刘颖, 赵修臣, 褚卫国. 一种C@MnO 2 纳米管超级电容器电极材料及其制备方法和用途. CN: CN104465123A, 2015-03-25.[67] 李晓军, 赵勇, 刘颖, 江鹏, 褚卫国, 赵修臣. 基于三维ZnO@MnO 2 复合纳米阵列叉指电极的超级电容器及其制备方法. CN: CN104465119A, 2015-03-25.[68] 褚卫国, 何岩, 王汉夫. 一种硼酸铁锂块状电极及其制备方法. CN: CN104425799A, 2015-03-18.[69] 米麟, 褚卫国, 王汉夫, 郭延军. 一种用作锂离子电池正极材料的硅酸铁锂的制备方法. CN: CN104425819A, 2015-03-18.[70] 王汉夫, 褚卫国. 一种变温样品台及热电性能测量方法. CN: CN104422711A, 2015-03-18.[71] 闫兰琴, 褚卫国, 宋志伟, 张先锋. 一种利用射频磁控溅射法制备单分散、尺寸可控纳米银颗粒的方法. CN: CN104372301A, 2015-02-25.[72] 王汉夫, 官爱强, 褚卫国. 平面型薄膜热电器件的制作方法和制作装置. CN: CN104347790A, 2015-02-11.[73] 王汉夫, 官爱强, 褚卫国. 垂直型薄膜热电器件的热电臂阵列的制作方法和制作装置. CN: CN104347789A, 2015-02-11.[74] 张文欣, 褚卫国, 王汉夫, 郭延军. 一种用作锂离子电池正极材料的三氧化钼及其制备方法. CN: CN104282888A, 2015-01-14.[75] 李晓军, 江鹏, 刘颖, 赵修臣, 褚卫国, 赵勇, 李振军. 一种碳纳米管/二氧化锰杂化超级电容器电极材料的制备方法及用途. CN: CN104201006A, 2014-12-10.[76] 宋志伟, 褚卫国. 一种超薄氧化硅膜材料及其制备方法. CN: CN104120404A, 2014-10-29.[77] 宋志伟, 褚卫国. 一种氮化硅膜材料及其制备方法. CN: CN104120403A, 2014-10-29.[78] 宋志伟, 褚卫国. 一种氧化硅膜材料及其制备方法. CN: CN104099581A, 2014-10-15.[79] 宋志伟, 褚卫国. 一种超薄氮化硅膜材料及其制备方法. CN: CN104099579A, 2014-10-15.[80] 王汉夫, 官爱强, 褚卫国, 郭延军, 金灏, 熊玉峰. 用于测量样品的热电性能的样品座及测量方法. CN: CN104062318A, 2014-09-24.[81] 徐丽华, 董凤良, 苗霈, 宋志伟, 闫兰琴, 褚卫国. 一种纳米级的铝刻蚀方法. CN: CN103789768A, 2014-05-14.[82] 刘海强, 褚卫国, 王汉夫. 一种铁掺杂锰酸锂锂离子电池正极材料的制备方法. CN: CN103794775A, 2014-05-14.[83] 董凤良, 徐丽华, 宋志伟, 褚卫国. 一种结构型吸波材料及其制作方法. CN: CN103779667A, 2014-05-07.[84] 董凤良, 徐丽华, 苗霈, 宋志伟, 闫兰琴, 褚卫国. 一种基于金属纳米光栅的微偏振片阵列的制作方法. CN: CN103760681A, 2014-04-30.[85] 海晓, 褚卫国, 王汉夫. 一种碳包覆的硅酸亚铁锂正极材料、制备方法及其用途. CN: CN103746116A, 2014-04-23.[86] 褚卫国, 王汉夫, 潘文智. 一种Li 2+x Fe 2-x (MoO 4 ) 3 材料的制备方法及其应用. CN: CN103570077A, 2014-02-12.[87] 何岩, 褚卫国, 王汉夫. 一种锂离子电池正极材料硼酸铁锂及其制备方法. CN: CN103545508A, 2014-01-29.[88] 宋志伟, 褚卫国. 一种低应力硅化合物超厚膜材料、制备方法及用途. CN: CN103484833A, 2014-01-01.[89] 褚卫国, 田瑞源, 王汉夫. 一种碳包覆锂离子电池正极材料磷酸铁锂及其制备方法. CN: CN103441268A, 2013-12-11.[90] 褚卫国, 米麟, 王汉夫. 一种六角桃核形硅酸铁锂聚集体及其制备方法. CN: CN103400981A, 2013-11-20.[91] 王汉夫, 官爱强, 李振伟, 褚卫国, 郭延军, 李晓军, 金灏, 祖敏, 刘秀. 一种测量平面型薄膜热电器件开路电压的系统. CN: CN203011995U, 2013-06-19.[92] 王汉夫, 官爱强, 褚卫国, 熊玉峰, 金灏, 郭延军. 热电材料测试样品座及其热电性能测量装置. CN: CN202837214U, 2013-03-27.[93] 王汉夫, 褚卫国. 含无机/有机异质结纳米线的制备方法. CN: CN101752211A, 2010-06-23.[94] 褚卫国, 王汉夫. Cu 3 Mo 2 O 9 催化剂及其制备方法和应用. 中国: CN101733116A, 2010-06-16.[95] 褚卫国, 王汉夫. Cu 3 Mo 2 O 9 催化剂及其制备方法和应用. CN: CN101733116A, 2010-06-16.[96] 褚卫国, 王汉夫. 一种多元氧化物纳米材料、纳米结构及其制备方法. CN: CN101723332A, 2010-06-09.[97] 褚卫国, 王汉夫. 一种三元氧化物纳米材料和纳米结构及其制备方法. CN: CN101723434A, 2010-06-09.
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Formation, structure and electrochemical performance of nano-sized Li2FeSiO4/C synthesized with the co-incorporation of citric acid and glucose followed by a two-step annealing. RSC ADVANCES[J]. 2014, 4(110): 64702-64710, https://www.webofscience.com/wos/woscc/full-record/WOS:000345826100041.[65] Zhang, Zhigang, Dong, Fengliang, Cheng, Teng, Qiu, Kang, Zhang, Qingchuan, Chu, Weiguo, Wu, Xiaoping. Nano-fabricated pixelated micropolarizer array for visible imaging polarimetry. REVIEWOFSCIENTIFICINSTRUMENTS[J]. 2014, 85(10): https://www.webofscience.com/wos/woscc/full-record/WOS:000344594200079.[66] Zhang ZhiGang, Dong FengLiang, Zhang QingChuan, Chu WeiGuo, Qiu Kang, Cheng Teng, Gao Jie, Wu XiaoPing. Fabrication of pixelated polarizer array and its application in polarization enhancement. 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科研活动
科研项目
( 1 ) 纳米测量技术标准的基础研究, 参与, 国家级, 2011-01--2015-12( 2 ) 高效储能锂离子电池聚阴离子正极材料研究, 主持, 部委级, 2011-01--2013-12( 3 ) 基于像素偏振片的实时相移数字全息技术, 参与, 国家级, 2015-01--2018-12( 4 ) 基于纳米光栅红外微偏振片阵列相关技术研究, 主持, 院级, 2015-09--2019-09
参与会议
(1)DDF method wgchu 2009-03-18(2)Small angle X-ray scattering (SAXS) analysis of nanoparticle size distribution -- dividing distribution function (DDF) method and its verification wgchu 2008-08-31(3)Particle size analysis—Small angle X-ray scattering method (SAXS) wgchu 2008-03-06(4)Structure and Stacking Fault of Ultrathin Fe Films Grown on Ge(111) Studied by X-ray Photoelectron Diffraction (XPD or XPED) 褚卫国 2007-07-27(5)Growth of Fe-Ge at various temperatures studied by XPD wgchu 2007-01-22
指导学生
已指导学生
潘文智 02 19124
田瑞源 01 19124
现指导学生
刘海强 01 19217
郭利民 02 19124
田毅 01 19217
蒋毅 01 19217
刘圣男 02 63222
谭兴华 01 19217