菜单总览
— 教职人员 —

郑庆彬

职位:

助理教授

教育背景:

博士(香港科技大学)

硕士(中国石油大学)

学士(中国石油大学)

研究领域
新型碳材料;透明导电薄膜;多功能柔性传感器;材料表面与界面;纳米复合材料;分子模拟
个人网站

http://repository.ust.hk/ir/AuthorProfile/zheng-qingbin

Email

zhengqingbin@cuhk.edu.cn

个人简介:


郑庆彬博士毕业于香港科技大学机械及航空航天学系,博士毕业后曾获得德国洪堡基金资助在德国德累斯顿莱布尼茨高分子研究所以“洪堡学者”身份从事为期两年的研究工作,之后曾任香港科技大学机械及航空航天学系研究助理教授及香港科技大学高等研究院“青年学者”。申报人长期从事新型碳材料与集成器件的先进制造加工及其在机械、电子、航空航天、医学等领域的应用,如多功能复合材料、柔性显示、柔性传感和柔性电磁屏蔽等。近十年来,申报人取得了一系列重要研究成果,已发表英文专著一部及高水平SCI收录论文50余篇,其中以第一作者/通讯作者身份在Progress in Materials Science, Advanced Functional Materials, ACS Nano, Materials Horizons, Nanoscale Horizon, ACS Applied Materials & Interfaces, Carbon等本领域顶级期刊发表文章20余篇,论文总计被引用3500余次,其中他H-index为29。曾独立主持德国洪堡基金,香港研究资助局优配研究金等项目。


学术著作:


专著:

论文:    ResearcherID     Google Scholar   

 

  • Lee J. H., Kim J. M., Liu D., Guo F. M., Zheng Q. B.*, Jeon S. K., Kim J. K.* (2019): Highly aligned, anisotropic carbon nanofiber films for multidirectional strain sensors with exceptional selectivity. Advanced Functional Materials, 1901623.
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  • Liu X.,  Liu D., Lee J. H., Zheng Q. B.*,  Du X.H., Zhang X. Y., Xu H. R., Wang Z. Y., Wu Y., Cui J., Mai Y. W., Kim J. K.* (2019): Spider-Web-Inspired Stretchable Graphene Woven Fabric for Highly Sensitive, Transparent, Wearable Strain Sensors. (highlighted by Nano WerkGraphene researchers are inspired by spider websACS Applied Materials & Interfaces, 11, 2282–2294.
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  • Zheng Q. B., Liu X., Xu H. R., Cheung M. S., Choi Y. W., Huang H. C., Lei H. Y., Shen X., Wang Z. Y., Wu Y., Kim S. Y., Kim J. K.  (2018): Sliced Graphene Foam films for Dual-functional Wearable Strain Sensors and Switches. (Inside front coverNanoscale  Horizons, 3, 35-44. 
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  • Shen X., Wang Z. Y., Wu Y., Liu X., He Y. B., Zheng Q. B., Yang Q. H., Kang F. Y., Kim J. K. (2018): Three-Dimensional Multilayer Graphene Web for Polymer Nanocomposites with Exceptional Transport Properties and Fracture Resistance. Materials Horizons, 5, 275-284.
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  • Wang Z. Y., Liu X., Shen X., Han N. M., Wu Y., Zheng Q. B., Jia J. J., Wang N., Kim J. K. (2018): Ultralight graphene honeycomb sandwich for stretchable light-emitting display. Advanced Functional Materials, 28, 1707043.
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  • Han N. M., Wang Z. Y., Shen X., Wu Y., Liu X., Zheng Q. B., Kim T. H., Yang J. L., Kim J. K. (2018): Graphene Size-Dependent Multifunctional Properties of Unidirectional Graphene Aerogel/Epoxy Nanocomposites. ACS Applied Materials & Interfaces, 10, 6580-6592.
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  • Wu Y., Wang Z. Y., Shen X., Liu X., Han N. M.,  Zheng Q. B., Mai Y. W., Kim J. K. (2018): Graphene/Boron Nitride−Polyurethane Microlaminates for Exceptional Dielectric Properties and High Energy Densities. ACS Applied Materials & Interfaces, 10, 26641−26652.
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  • Huang J. Q., Chong W. G., Zheng Q. B., Xu Z. L., Cui J., Yao S. S., Wang C. W., Kim J. K. (2018): Understanding the roles of activated porous carbon nanotubes as sulfur support and separator coating for lithium-sulfur batteries. Electrochimica Acta, 268, 1-9.
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  • Liu X., Tang C., Du X. H., Xiong S., Xi S. Y., Liu Y. F., Shen X., Zheng Q. B.*, Wang Z. Y., Wu Y., Horner A., Kim J. K. (2017): A highly sensitive graphene woven fabric strain sensor for wearable wireless musical instrumentMaterials Horizons, 4, 477-486.
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  • Wu Y., Wang Z. Y., Liu X., Shen X., Zheng Q. B.*, Xue Q., Kim J. K. (2017): Ultralight graphene foam/conductive polymer composites for exceptional electromagnetic interference shielding. ACS Applied Materials & Interfaces, 9, 9059–9069.
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  • Wang Z. Y., Han N. M., Wu Y., Liu X., Shen X., Zheng Q. B.,  Kim J. K.  (2017): Ultrahigh dielectric constant and low loss of highly-aligned graphene aerogel/poly(vinyl alcohol) composites with insulating barriers. Carbon, 123, 385-394.
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  • Zheng Q. B., Li Z. G., Yang J. H., Kim J. K. (2014): Graphene oxide-based transparent conductive filmsProgress in Materials Science, 64, 200-247.
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  • Huang, J. H., Zheng, Q. B., Kim, J. K., Li Z. G. (2013): A molecular beacon and graphene oxide-based fluorescent biosensor for Cu2+ detection. Biosensors & Bioelectronics, 43, 379-383.
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  • Yousefi, N., Lin X. Y., Zheng, Q. B., Shen X., Pothnis J. R., Jia J. J., Zussman E., Kim J. K. (2013): Simultaneous in situ reduction, self-alignment and covalent bonding in graphene oxide/epoxy composites. Carbon, 59, 406-417.
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  • Yousefi, N., Gudarzi, M. M., Zheng, Q. B., Lin X. Z., Shen X., Jia J. J., Sharif F., Kim J. K. (2013): Highly aligned, ultralarge-size reduced graphene oxide/polyurethane nanocomposites: mechanical properties and moisture permeability. Composites Part A: Applied Science and Manufacturing, 49, 42-50.
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  • Zheng Q. B., Zhang B., Lin X. Y., Shen X., Yousefi N., Huang Z. D., Li Z. G., Kim J.K. (2012): Highly transparent and conducting ultra-large graphene oxide/single-walled carbon nanotube hybrid films produced by Langmuir-Blodgett assembly. Journal of Materials Chemistry, 22, 25072-25082.
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  • Lin X. Y., Shen X., Zheng Q. B., Yousefi N., Ye L., Mai Y. W., Kim J. K. (2012): Fabrication of highly-aligned, conductive, and strong graphene papers using ultra-large graphene oxide sheets. ACS Nano, 6, 10708-10719.
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  • Huang Z. D., Zhang B., Liang R., Zheng Q. B., Oh S., Lin X. Y., Yousefi N., Kim J.-K. (2012): Effects of reduction process and carbon nanotube content on the supercapacitive performance of flexible graphene oxide papers. Carbon, 50, 4239-4251.
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  • Yousefi N., Gudarzi M. M., Zheng Q. B., Aboutalebi S. H., Sharif F., Kim J.-K. (2012): Self-alignment and high electrical conductivity of ultralarge graphene oxide/polyurethane nanocomposites. Journal of Materials Chemistry, 22, 12709-12717.
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  • Huang Z. D., Zhang B., Oh S., Zheng Q. B., Lin X. Y., Yousefi N., Kim J.-K. (2012): Self-assembled reduced graphene oxide/carbon nanotube thin films as electrodes for supercapacitors. Journal of Materials Chemistry, 22, 3591-3599.
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  • Zheng Q. B., Ip W. H., Lin X. Y., Yousefi N., Yeung K. K., Li Z. G., Kim J.K. (2011): Transparent conductive films consisting of ultra-large graphene sheets produced by Langmuir-Blodgett assemblyACS Nano, 5, 6039-6051.
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  • Aboutalebi, S. H., Gudarzi M. M., Zheng Q. B., Kim J. K. (2011): Spontaneous formation of liquid crystals in ultra-large graphene oxide dispersions. Advanced Functional Materials, 21, 2978-2988.
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  • Zheng Q. B., Gudarzi M. M., Wang S. J., Geng Y., Li Z. G., Kim J.K. (2011): Improved electrical and optical characteristics of transparent graphene thin films by acid and doping treatments. Carbon, 49, 2905-2916.
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  • Zhang B., Zheng Q. B., Huang Z. D., Oh S., Kim J.-K. (2011): SnO2-graphene-carbon nanotube mixture for anode material with improved rate capacities. Carbon, 49, 4524-4534.
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  • Zheng Q. B., Geng Y., Wang S. J., Li Z. G., Kim J.K. (2010): Effects of functional groups on the mechanical and wrinkling properties of graphene sheets. Carbon, 48, 4315-4322.
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  • Zheng Q. B., Xia D., Xue Q. Z., Yan K. Y., Gao X. L., Li Q. (2009): Computational analysis of effect of modification on the interfacial characteristics of a carbon nanotube-polyethylene composite system. Applied Surface Science, 6, 3534-3543.
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  • Zheng Q. B., Xue Q. Z., Yan K. Y., Gao X. L., Li Q., Hao L. Z. (2008): Effect of chemisorption on the interfacial bonding characteristics of carbon nanotube-polymer composites. Polymer, 49, 800-808.
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  • Zheng Q. B., Xue Q. Z., Yan K. Y., Gao X. L., Li Q., Hao L. Z. (2008): Influence of chirality on the interfacial bonding characteristics of carbon nanotube polymer composites. Journal of Applied Physics, 103, 044302.
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  • Zheng Q. B., Xue Q. Z., Yan K. Y., Hao L. Z., Li Q., Gao X. L. (2007): Investigation of molecular interactions between SWNT and polyethylene /polypropylene /polystyrene /polyaniline MoleculesJournal of Physical Chemistry C, 111, 4628-4637.