博士（香港科技大学）

学士及硕士（中国石油大学）

郑庆彬，香港中文大学（深圳）理工学院助理教授，博士生导师，校长青年学者，德国洪堡学者，香港科技大学机械工程学博士。郑教授曾任德国德累斯顿莱布尼茨高分子研究所“洪堡学者”，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“青年学人”，主持国家人才项目，国家自然科学基金，广东省自然科学基金，深圳市自然科学基金，香港研究资助局优配研究金，德国洪堡基金等项目，获得香港中文大学（深圳）理工学院卓越科研奖，斯坦福大学前2%科学家，Research.com全球顶尖材料科学家等荣誉。

郑教授长期从事纳米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，取得了一系列重要研究成果，已在Progress in Materials Science、Materials Today、Advanced Materials、Advanced Functional Materials、ACS Nano、Angewandte Chemie International Edition、Carbon等本领域顶级期刊发表文章90余篇，论文总计被引用11,000余次，H-index为52。

专著:

• Zheng Q. B., Kim J. K. Graphene for Transparent Conductors: Synthesis, Properties and Applications (ISBN 978-1-4939-2768-5). Springer, New York. 2015, pp. 220.

代表性论文（* 通讯作者）

ResearcherID     Google Scholar    ORCID

1. Xue J., Liu D., Li D., Hong T. Z., Li C. B., Zhu Z. F., Sun Y. X., Gao X. B., Guo L., Shen X., Ma P. C., Zheng Q. B.* (2024): New Carbon Materials for Multifunctional Soft Electronics. Advanced Materials, 2312596.
2. Zhang F., Sun Y. X., Guo L., Zhang Y. H., Liu D., Feng W.*, Shen X.*, Zheng Q. B.* (2024): Microstructural Welding Engineering of Carbon Nanotube/Polydimethylsiloxane Nanocomposites with Improved Interfacial Thermal Transport. Advanced Functional Materials, 34, 2311906.
3. Wu Y., An C., Guo Y. R., Zong Y. Y., Jiang N. S., Zheng Q. B.*, Yu Z. Z*. (2024): Highly Aligned Graphene Aerogels for Multifunctional Composites, Nano-Micro Letters, 16, 118.
4. Wu J. Y., Liu D., Sun Y. X., Wei B. K., Dai K., Sun Y. Q., Zhang F., Li C. B., Xue J., Zhu Z. F., Gao X. B., Zheng Q. B. * (2024): Ultralight anisotropic Ti3C2Tx MXene/Carbon nanotube hybrid aerogel for highly efficient solar steam generation. Carbon, 223, 118976.
5. Xie J. W., Zhou G., Sun Y. X., Zhang F., Kang F. Y., Li B. H., Zhao Y., Zhang Y. H. *, Lin L.*, Zheng Q. B.* (2023): Multifunctional Liquid Metal-Bridged Graphite Nanoplatelets/Aramid Nanofiber Film for Thermal Management. Small, 2305163.
6. Xie J. W., Zhang Y. H., Dai J. M., Xie Z. X., Xue J., Dai K., Zhang F., Cheng J. Y., Kang F. Y., Li B. H., Zhao Y., Lin L.*, Zheng Q. B.* (2023): Multifunctional MoSe₂@MXene Heterostructure-Decorated Cellulose Fabric for Wearable Thermal Therapy, Small, 19, 2205853.
7. Cheng J. Y., Zhang H. B., Wang H. H., Huang Z. H., Raza H., Hou C. X., Zheng G. P., Zhang D. Q. *, Zheng Q. B.*, Che R. C. * (2022): Tailoring Self‐Polarization of Bimetallic Organic Frameworks with Multiple Polar Units Toward High‐Performance Consecutive Multi‐Band Electromagnetic Wave Absorption at Gigahertz (Highly Cited Paper). Advanced Functional Materials, 32, 2201129.
8. Cheng J. Y., Zhang H. B., Ning M. Q., Raza H., Hou C. X., Zhang D. Q.*, Zheng G. P., Zheng Q. B.*, Che R. C. * (2022): Emerging materials and designs for low- and multi-band electromagnetic wave absorbers: the search for dielectric and magnetic synergy? (Highly Cited Paper). Advanced Functional Materials, 32, 2200123.
9. Zhang H., Chen H. M., Lee J. H., Kim E., Chan K. Y., Venkatesan H., Adegun M. H., Agbabiaka O. G., Shen X.,* Zheng Q. B., Yang J. L.,* and Kim J. K. * (2022): Bioinspired Chromotropic Ionic Skin with In-Plane Strain/Temperature/Pressure Multimodal Sensing and Ultrahigh Stimuli Discriminability. Advanced Functional Materials, 2208362.
10. Zhang H. B., Cheng J. Y. *, Wang H. H, Huang Z. H., Zheng Q. B., Zheng G. P., Zhang D. Q. *, Che R. C. *, Cao M. S. * (2022): Initiating VB-Group Laminated NbS2 Electromagnetic Wave Absorber toward Superior Absorption Bandwidth as Large as 6.48 GHz through Phase Engineering Modulation (Highly Cited Paper). Advanced Functional Materials, 32, 2108194. 
11. Yang, L. Z., Yan L. T., Niu W. J., Feng Y., Fu Q. J., Zhang S., Zhang Y. H., Li L. J., Gu X., Dai P., Liu D. D., Zheng Q. B.*, Zhao X. B. * (2022) Adsorption in Reversed Order of C2 Hydrocarbons on an Ultramicroporous Fluorinated Metal-Organic Framework. Angewandte Chemie International Edition, 61, e202204046.
12. Dang C., Zhang F., Li Y. H., Jin Z. X., Cheng Y. B., Feng Y. F., Wang X. J., Zhang C. Z., Chen Y., Shao C. Y.,* Zheng, Q. B.*, Qi H. S.* (2022): Lithium Bonds Enable Small Biomass Molecule-Based Ionoelastomers with Multiple Functions for Soft Intelligent Electronics. Small, 18, 2200421.
13. Zhang Y. H., Wang W., Zhang F., Dai K., Li C. B., Fan Y., Chen G. M.*, Zheng Q. B.* (2022): Soft Organic Thermoelectric Materials: Principles, Current State of the Art and Applications. Small, 18, 2104922.
14. Cheng J. Y., Li C. B., Xiong Y. F., Zhang H. B., Raza H., Ullah S., Wu J. Y., Zheng G. P., Cao Q.*, Zhang D. Q., Zheng Q. B.*, Che R. C.* (2022): Recent Advances in Design Strategies and Multifunctionality of Flexible Electromagnetic Interference Shielding Materials (Highly Cited Paper). Nano-Micro Letters, 14, 80.
15. Zhang F., Li C. B., Zhang Y. H., Sun Y. X., Yao X. M., Guo L., Wu J. Y., Dai K., Wu J. T., Zheng Q. B.* (2022): Facile preparation of large-scale expanded graphite/polydimethylsiloxane composites for Highly-efficient electromagnetic interference shielding, Journal of Materials Chemistry A, 10, 23145.
16. Zhang Y. H., Wang W., Xie J. W., Dai K., Zhang F., Zheng Q. B.* (2022): Smart and Flexible CNTs@MXene Heterostructure-Decorated Cellulose Films with Excellent Electrothermal/Photothermal Conversion and EMI Shielding Performances. Carbon, 200, 491-499.
17. Zhang Y. H., Wang W., Zhang F., Huang L. Q., Dai K., Li C. B., Sun Y. X., Ren D. H., Wu J. Y., Zheng Q. B.* (2022): Micro-diamond Assisted Bidirectional Tuning of Thermal Conductivity in Multifunctional Graphene Nanoplatelets/nanofibrillated Cellulose Films. Carbon, 189, 265-275.
18. Zhang F., Ren D. H., Huang L. Q., Zhang Y. H., Sun Y. X., Liu D., Zhang Q., Feng W.*, Zheng Q. B.* (2021): Three-Dimensional Interconnected Conductive Graphite Nanoplatelet Welded Carbon Nanotube Networks for Stretchable Conductors (This article also appears in: Hot Topic: Carbon, Graphite, and Graphene), Advanced Functional Materials, 31, 2107082.
19. Zhang H., Liu D., Lee J.H., Chen H. M., Kim E., Shen X.*, Zheng Q. B.*, Yang J. L.*, Kim J. K.*. (2021): Anisotropic wrinkled and crack-bridging structure for ultrasensitive, highly selective multidirectional strain sensors, Nano-Micro Letters, 13, 122.
20. Shen X., Zheng Q. B., Kim J. K.* (2021): Rational design of two-dimensional nanofillers for three dimensional polymer nanocomposites toward multifunctional applications (Highly Cited Paper). Progress in Materials Science, 115, 100708.
21. Zheng Q. B., Lee J. H., Shen X., Chen X. D., Kim J. K.* (2020): Graphene-Based Wearable Piezoresistive Physical Sensors (Highly Cited Paper). Materials Today, 36, 158-179.
22. Guo F. M, Shen X., Zhou J. M., Liu D., Zheng Q. B., Yang J., Jia B., Lau A. K. T., Kim J. K.* (2020): Highly Thermally Conductive Dielectric Nanocomposites with Synergistic Alignments of Graphene and Boron Nitride Nanosheets (Highly Cited Paper). Advanced Functional Materials, 30, 1910826.
23. 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, 29, 1901623.
24. 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.
25. Zheng Q. B., Li Y. G., Yang J. H., Kim J. K.* (2014): Graphene oxide-based transparent conductive films (Highly Cited Paper). Progress in Materials Science, 64, 200-247.
26. 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 ultralarge graphene oxide sheets. ACS Nano, 6, 10708-10719.
27. 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 assembly (Highly Cited Paper). ACS Nano, 5, 6039-6051.
28. 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.
29. Aboutalebi S. H., Gudarzi M. M., Zheng Q. B., Kim J. K.* (2011): Spontaneous formation of liquid crystal in ultra-large graphene oxide dispersions. Advanced Functional Materials, 21, 2978-2988.
30. 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.