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李晓明(助理研究员)

       

  

  李晓明,硕士,助理研究员;山西省吕梁人,1986年3月生。

   

   

  教育及工作经历:

  2005-2009年,中北大学,高分子材料与科学专业,学士

  2010-2013年,兰州理工大学大学,材料学专业,硕士

  2013-2017年,中国科学院山西煤炭化学研究所,研究实习员

  2017-至今,中国科学院山西煤炭化学研究所,助理研究员

   

   

  研究方向:石墨烯功能材料,包括石墨烯功能浆料、石墨烯改性高分子、石墨烯热管理材料。

   

  Email:lixiaoming@sxicc.ac.cn

   

   

  论文:

  [1] Hua C. J., Li X. M., Shen L. J., et al. Influence of co-solvent hydroxyl group number on properties of water-based conductive carbon pastes[J]. Particuology. 2017,33:35-41.

  [2] Tong Yun-Xiao, Li Xiao-Ming, Xie Li-Jing, et al. Nitrogen-doped hierarchical porous carbon derived from block copolymer for supercapacitor[J]. Energy Storage Materials. 2016,3:140-148.

  [3] Gao Y. D., Zhang Y. Y., Zhang Y., et al. Three-dimensional paper-like graphene framework with highly orientated laminar structure as binder-free supercapacitor electrode[J]. Journal of Energy Chemistry. 2016,25(1):49-54.

  [4] Su F. Y., Xie L. J., Sun G. H., et al. Theoretical research progress on the use of graphene in different electrochemical processes[J]. New Carbon Materials. 2016,31(4):363-377.

  [5] Y. Wang, Kong L. B., Li X. M., et al. Mesoporous carbons for supercapacitors obtained by the pyrolysis of block copolymers%B New Carbon Materials[J]. 2016,4%N 30:302-209.

  [6] Xie L. J., Sun G. H., Xie L. F., et al. A high energy density asymmetric supercapacitor based on a CoNi-layered double hydroxide and activated carbon[J]. New Carbon Materials. 2016,31(1):37-45.

  [7] Xie L. J., Sun G. H., Su F. Y., et al. Hierarchical porous carbon microtubes derived from willow catkins for supercapacitor applications[J]. Journal of Materials Chemistry A. 2016,4(5):1637-1646.

  [8] Gao Y. D., Kong Q. Q., Liu Z., et al. Graphene oxide aerogels constructed using large or small graphene oxide with different electrical, mechanical and adsorbent properties[J]. RSC Advances. 2016,6(12):9851-9856.

  [9] Lei H., Liu Z., He C., et al. Graphene enhanced low-density polyethylene by pretreatment and melt compounding[J]. RSC Advances. 2016,6(103):101492-101500.

  [10] 谢莉婧, 孙国华, 谢龙飞, 等. 基于CoNi-双金属氢氧化物//AC非对称超级电容器的构筑(英文)[J]. 新型炭材料. 2016,(01):37-45.

  [11] 苏方远, 谢莉婧, 孙国华, 等. 石墨烯在电化学储能过程中理论研究进展[J]. 新型炭材料. 2016,(04):363-377.

  [12] Xie L. J., Su F. Y., Xie L. F., et al. Self-Assembled 3D Graphene-Based Aerogel with Co3O4 Nanoparticles as High-Performance Asymmetric Supercapacitor Electrode[J]. Chemsuschem. 2015,8(17):2917-2926.

  [13] Liu Zhuo, Kong Qing-Qiang, Chen Cheng-Meng, et al. From two-dimensional to one-dimensional structures: SiC nano-whiskers derived from graphene via a catalyst-free carbothermal reaction[J]. RSC Advances. 2015,5(8):5946-5950.

  [14] Liu Y. Z., Chen C. M., Li Y. F., et al. Crumpled reduced graphene oxide by flame-induced reduction of graphite oxide for supercapacitive energy storage[J]. Journal of Materials Chemistry A. 2014,2(16):5730-5737.

  [15] Kong L. B., Li X. M., Liu M. C., et al. A hydrothermal process for the fabrication of nickel foam based NiO and Co3O4 nanostructures with excellent properties for electrochemical capacitors[J]. Advances in Energy Science and Technology, Pts 1-4. 2013,291-294:786-790.

  [16] Liu M. C., Kang L., Kong L. B., et al. Facile synthesis of NiMoO4 center dot xH(2)O nanorods as a positive electrode material for supercapacitors[J]. RSC Advances. 2013,3(18):6472-6478.

  [17] Liu M. C., Kong L. B., Lu C., et al. Design and synthesis of CoMoO4-NiMoO4 center dot xH(2)O bundles with improved electrochemical properties for supercapacitors[J]. Journal of Materials Chemistry A. 2013,1(4):1380-1387.

  [18] Liu Mao. Cheng., Kong L. B., Lu C., et al. Waste paper based activated carbon monolith as electrode materials for high performance electric double-layer capacitors[J]. RSC Advances. 2012,2(5):1890-1896.

  [19] Liu M. C., Kong L. B., Lu C., et al. A Sol-Gel Process for the Synthesis of NiCo2O4 Having Improved Specific Capacitance and Cycle Stability for Electrochemical Capacitors[J]. Journal of the Electrochemical Society. 2012,159(8):A1262-A1266.

  [20] Liu M. C., Kong L. B., Lu C., et al. A Sol-Gel Process for Fabrication of NiO/NiCo2O4/Co3O4 Composite with Improved Electrochemical Behavior for Electrochemical Capacitors[J]. ACS Applied Materials & Interfaces. 2012,4(9):4631-4636.

  [21] Liu M. C., Kong L. B., Ma X. J., et al. Hydrothermal process for the fabrication of CoMoO4 center dot 0.9H(2)O nanorods with excellent electrochemical behavior[J]. New Journal of Chemistry. 2012,36(9):1713-1716.

  [22] Kong L. B., Deng L., Li X. M., et al. Fabrication of flower-like Ni-3(NO3)(2)(OH)(4) and their electrochemical properties evaluation[J]. Materials Research Bulletin. 2012,47(7):1641-1647.

   

   

  授权专利:

  [1] 陈成猛; 李晓明; 蔡榕; 苏方远; 白锦宇; 刘卓; 高逸丹. 一种石墨烯基低电阻导电油墨及其制备方法. 2015.6.30. ZL201510372497.4

  [2] 陈成猛; 李晓明; 苏方; 谢莉婧; 孔庆强; 刘卓. 一种轻质固体展示装置. 2016.10.14, ZL201621124402.3

  [3] 陈成猛; 谢莉婧; 孔庆强; 苏方远; 李晓明; 刘卓; 蔡榕. 一种还原氧化石墨烯/酚醛树脂基活性炭原位复合材料的制备方法. 2015.2.6, ZL201510062450.8

  [4] 陈成猛; 谢莉婧; 孔庆强; 苏方远; 李晓明; 刘卓; 张长明; 蔡榕. 一种基于柳絮的活性炭制备方法. 2015.2.6, ZL201510062117.7

  [5] 陈成猛; 孔庆强; 王大力; 张兴华; 苏方远; 李晓明; 王伟; 苏小威. 一种快速制备高性能石墨烯的方法. 2015.2.6, ZL201510062040.3

  [6] 陈成猛; 谢莉婧; 孔庆强; 苏方远; 李晓明; 刘卓. 一种制备氧化钴/石墨烯纳米复合材料的方法. 2015.5.8, ZL201510232487.0

  [7] 陈成猛; 刘卓; 蔡榕; 李晓明; 孔庆强. 一种制备纳米碳化硅晶须的方法. 2014.3.24, ZL201410110623.4

  [8] 陈成猛; 孔庆强; 王大力; 石久龙; 刘卓; 李晓明; 王炜; 苏小威. 一种石墨烯快速膨胀炉. 2015.7.29, ZL201520557220.4

  [9] 陈成猛; 高建国; 刘卓; 孔庆强; 张兴华; 李晓明; 蔡榕. 一种制备炭纤维与石墨烯复合纸的方法. 2013.10.14, ZL201310478553.3

  [10] 陈成猛; 李晓明; 孔庆强; 谢莉婧; 苏方远; 何敬奎. 一种分级分散法制备石墨烯水性分散液的方法及装置. 2016.5.18, ZL201610330047.3

团队成员  

李晓明(助理研究员)

       

  

  李晓明,硕士,助理研究员;山西省吕梁人,1986年3月生。

   

   

  教育及工作经历:

  2005-2009年,中北大学,高分子材料与科学专业,学士

  2010-2013年,兰州理工大学大学,材料学专业,硕士

  2013-2017年,中国科学院山西煤炭化学研究所,研究实习员

  2017-至今,中国科学院山西煤炭化学研究所,助理研究员

   

   

  研究方向:石墨烯功能材料,包括石墨烯功能浆料、石墨烯改性高分子、石墨烯热管理材料。

   

  Email:lixiaoming@sxicc.ac.cn

   

   

  论文:

  [1] Hua C. J., Li X. M., Shen L. J., et al. Influence of co-solvent hydroxyl group number on properties of water-based conductive carbon pastes[J]. Particuology. 2017,33:35-41.

  [2] Tong Yun-Xiao, Li Xiao-Ming, Xie Li-Jing, et al. Nitrogen-doped hierarchical porous carbon derived from block copolymer for supercapacitor[J]. Energy Storage Materials. 2016,3:140-148.

  [3] Gao Y. D., Zhang Y. Y., Zhang Y., et al. Three-dimensional paper-like graphene framework with highly orientated laminar structure as binder-free supercapacitor electrode[J]. Journal of Energy Chemistry. 2016,25(1):49-54.

  [4] Su F. Y., Xie L. J., Sun G. H., et al. Theoretical research progress on the use of graphene in different electrochemical processes[J]. New Carbon Materials. 2016,31(4):363-377.

  [5] Y. Wang, Kong L. B., Li X. M., et al. Mesoporous carbons for supercapacitors obtained by the pyrolysis of block copolymers%B New Carbon Materials[J]. 2016,4%N 30:302-209.

  [6] Xie L. J., Sun G. H., Xie L. F., et al. A high energy density asymmetric supercapacitor based on a CoNi-layered double hydroxide and activated carbon[J]. New Carbon Materials. 2016,31(1):37-45.

  [7] Xie L. J., Sun G. H., Su F. Y., et al. Hierarchical porous carbon microtubes derived from willow catkins for supercapacitor applications[J]. Journal of Materials Chemistry A. 2016,4(5):1637-1646.

  [8] Gao Y. D., Kong Q. Q., Liu Z., et al. Graphene oxide aerogels constructed using large or small graphene oxide with different electrical, mechanical and adsorbent properties[J]. RSC Advances. 2016,6(12):9851-9856.

  [9] Lei H., Liu Z., He C., et al. Graphene enhanced low-density polyethylene by pretreatment and melt compounding[J]. RSC Advances. 2016,6(103):101492-101500.

  [10] 谢莉婧, 孙国华, 谢龙飞, 等. 基于CoNi-双金属氢氧化物//AC非对称超级电容器的构筑(英文)[J]. 新型炭材料. 2016,(01):37-45.

  [11] 苏方远, 谢莉婧, 孙国华, 等. 石墨烯在电化学储能过程中理论研究进展[J]. 新型炭材料. 2016,(04):363-377.

  [12] Xie L. J., Su F. Y., Xie L. F., et al. Self-Assembled 3D Graphene-Based Aerogel with Co3O4 Nanoparticles as High-Performance Asymmetric Supercapacitor Electrode[J]. Chemsuschem. 2015,8(17):2917-2926.

  [13] Liu Zhuo, Kong Qing-Qiang, Chen Cheng-Meng, et al. From two-dimensional to one-dimensional structures: SiC nano-whiskers derived from graphene via a catalyst-free carbothermal reaction[J]. RSC Advances. 2015,5(8):5946-5950.

  [14] Liu Y. Z., Chen C. M., Li Y. F., et al. Crumpled reduced graphene oxide by flame-induced reduction of graphite oxide for supercapacitive energy storage[J]. Journal of Materials Chemistry A. 2014,2(16):5730-5737.

  [15] Kong L. B., Li X. M., Liu M. C., et al. A hydrothermal process for the fabrication of nickel foam based NiO and Co3O4 nanostructures with excellent properties for electrochemical capacitors[J]. Advances in Energy Science and Technology, Pts 1-4. 2013,291-294:786-790.

  [16] Liu M. C., Kang L., Kong L. B., et al. Facile synthesis of NiMoO4 center dot xH(2)O nanorods as a positive electrode material for supercapacitors[J]. RSC Advances. 2013,3(18):6472-6478.

  [17] Liu M. C., Kong L. B., Lu C., et al. Design and synthesis of CoMoO4-NiMoO4 center dot xH(2)O bundles with improved electrochemical properties for supercapacitors[J]. Journal of Materials Chemistry A. 2013,1(4):1380-1387.

  [18] Liu Mao. Cheng., Kong L. B., Lu C., et al. Waste paper based activated carbon monolith as electrode materials for high performance electric double-layer capacitors[J]. RSC Advances. 2012,2(5):1890-1896.

  [19] Liu M. C., Kong L. B., Lu C., et al. A Sol-Gel Process for the Synthesis of NiCo2O4 Having Improved Specific Capacitance and Cycle Stability for Electrochemical Capacitors[J]. Journal of the Electrochemical Society. 2012,159(8):A1262-A1266.

  [20] Liu M. C., Kong L. B., Lu C., et al. A Sol-Gel Process for Fabrication of NiO/NiCo2O4/Co3O4 Composite with Improved Electrochemical Behavior for Electrochemical Capacitors[J]. ACS Applied Materials & Interfaces. 2012,4(9):4631-4636.

  [21] Liu M. C., Kong L. B., Ma X. J., et al. Hydrothermal process for the fabrication of CoMoO4 center dot 0.9H(2)O nanorods with excellent electrochemical behavior[J]. New Journal of Chemistry. 2012,36(9):1713-1716.

  [22] Kong L. B., Deng L., Li X. M., et al. Fabrication of flower-like Ni-3(NO3)(2)(OH)(4) and their electrochemical properties evaluation[J]. Materials Research Bulletin. 2012,47(7):1641-1647.

   

   

  授权专利:

  [1] 陈成猛; 李晓明; 蔡榕; 苏方远; 白锦宇; 刘卓; 高逸丹. 一种石墨烯基低电阻导电油墨及其制备方法. 2015.6.30. ZL201510372497.4

  [2] 陈成猛; 李晓明; 苏方; 谢莉婧; 孔庆强; 刘卓. 一种轻质固体展示装置. 2016.10.14, ZL201621124402.3

  [3] 陈成猛; 谢莉婧; 孔庆强; 苏方远; 李晓明; 刘卓; 蔡榕. 一种还原氧化石墨烯/酚醛树脂基活性炭原位复合材料的制备方法. 2015.2.6, ZL201510062450.8

  [4] 陈成猛; 谢莉婧; 孔庆强; 苏方远; 李晓明; 刘卓; 张长明; 蔡榕. 一种基于柳絮的活性炭制备方法. 2015.2.6, ZL201510062117.7

  [5] 陈成猛; 孔庆强; 王大力; 张兴华; 苏方远; 李晓明; 王伟; 苏小威. 一种快速制备高性能石墨烯的方法. 2015.2.6, ZL201510062040.3

  [6] 陈成猛; 谢莉婧; 孔庆强; 苏方远; 李晓明; 刘卓. 一种制备氧化钴/石墨烯纳米复合材料的方法. 2015.5.8, ZL201510232487.0

  [7] 陈成猛; 刘卓; 蔡榕; 李晓明; 孔庆强. 一种制备纳米碳化硅晶须的方法. 2014.3.24, ZL201410110623.4

  [8] 陈成猛; 孔庆强; 王大力; 石久龙; 刘卓; 李晓明; 王炜; 苏小威. 一种石墨烯快速膨胀炉. 2015.7.29, ZL201520557220.4

  [9] 陈成猛; 高建国; 刘卓; 孔庆强; 张兴华; 李晓明; 蔡榕. 一种制备炭纤维与石墨烯复合纸的方法. 2013.10.14, ZL201310478553.3

  [10] 陈成猛; 李晓明; 孔庆强; 谢莉婧; 苏方远; 何敬奎. 一种分级分散法制备石墨烯水性分散液的方法及装置. 2016.5.18, ZL201610330047.3

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