陶肖明 - 香港理工大学 - 纺织与服装学系

个人简介

Prof. Tao is Chair Professor of Textile Technology, Institute of Textiles and Clothing, The Hong Kong Polytechnic University since 2002. Currently she holds the Vincent and Lily Woo Endowed Professorship in Textile Technology generously supported by the Vincent and Lily Woo Trust. She obtained a BEng in textile engineering from East China Institute of Textile Science and Technology with a 1st class prize; and a PhD in textile physics from University of New South Wales in Australia. Prof. Tao is former World President from 2007 to 2010, an elected Fellow of the Textile Institute, elected Fellow of American Society of Mechanical Engineering and elected Fellow of the Royal Society of Arts, Design and Commercial Applications, UK. Prof. Tao is Editor-in-Chief for Handbook of Smart Textiles by Springer and serves on Editorial Board of more than 10 key academic journals of the field. Prof. Tao was the Head of Institute of Textiles and Clothing from 2003 to 2011. During this period of time, she guided the Institute in its endeavor to become one of the leading fashion and textile departments in the world. She founded the Nanotechnology Centre for Functional and Intelligent Textile and Apparel. By working closely with the industry, Prof. Tao successfully led the PolyU team to win an ITF grant of over HK$330 million for hosting Hong Kong Research Centre for Textiles and Clothing, the largest single research grant that the University has ever received. As Principal Investigator, she has successfully attracted research grants over 154 million Hong Kong dollars in the last 20 years.

研究领域

We, Smart Textiles and Apparel Research (STAR) group, are inspired to work at the very cutting-edge in creating new scientific knowledge and developing novel technologies in soft, deformable fibrous materials and textile structures for the benefit of mankind. Our interdisciplinary research team comprises energetic and talent physicists, materials scientists; electronic, mechanical, chemical and textile engineers as well as fashion/textile designers.

近期论文

查看导师新发文章（温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

Tao XM*, 2020. Liquid metal gives transmission lines a softer touch, Nature Electronics, 3, 300-301. Yan W, Dong C, Xiang Y, Jiang S, Leber A, Loke G, Xu W, Hou C, Zhou S, Chen M, Hu R, Shum PP, Wei L, Jia X, Sorin F, Tao XM, Tao GM, 2020. Thermally drawn advanced functional fibers: New frontier of flexible electronics, Materials Today, 35, 168-194. Shi JD, Liu S, Zhang L, Yang B, Shu L, Yang Y, Ren M, Wang Y, Chen JW, Chen W, Chai Y, Tao XM*, 2020. Smart textile-integrated Microelectronic systems for wearable applications, Advanced Materials, 32(5): 1091958. Yin R, Yang B, Ding XJ, Liu S, Zeng W, Yang S, Li J and Tao XM*, 2020. Wireless Multi-Stimulus-Responsive Fabric-based Actuators for Soft Robotic, Human-Machine Interactive and Wearable Applications", Advanced Materials Technology, https://doi.org/10.1002/admt.202000341. Yang B, Wang X, Xiong Y, Liu S, Liu SR, Guo X, Tao XM*, 2020. Smart bionic morphing leg mannequin for pressure assessment of compression garment, Smart Materials and Structures, 29(2020) 055041. Li J, Wong WY and Tao XM*, 2020. Recent advances in soft functional materials: Preparation, functions and applications, Nanoscale, 12(3):1281-1306. Li C, Yang Y, Wu Y, Tao XM, Chen W, 2020. High-Performance Piezocomposite Energy Harvesters by Constructing Bionic Ion Channels, Advanced Materials Technology, 5(5): 200050. Li Q, Wang Y, Jiang S, Ding X, Tao XM and Wang X, 2020. Investigation into tensile hysteresis of polyurethane-containing textile substrates for coated strain sensors, Materials and Design, 188:108451. Mi HY, Li H, Jing X, He P, Feng PY, Tao XM, Liu YJ, Liu CT and Shen CY, 2020. Silk and silk composite aerogel based biocompatiable trioelectric nanogenerators for efficient energy harvesting, Industrial and Engineering Chemistry Research, http://doi.org/10.1021/acs.ircr.oc01117 Yin R, Tao XM* and Xu BG, 2020. Yarn and fabric properties in a modified ring spinning system considering the effect of the friction surface of the false-twister, Textile Research Journal, 90(5-6):572-580. Jing X, Li H, Mi XY, Feng PY, Tao XM, Liu YJ, Liu CT, Shen CY, 2020. Enhancing Performance of Stretchable and Transparent Triboelectric Nanogenerator by Optimizing Hydrogel Ionic Electrode Property, ACS Applied Materials & Interfaces, 12, 20, 23474–23483. Jing X, Li H, Mi XY, Feng PY, Tao XM, Liu YJ, Liu CT, Shen CY, 2020. A flexible semitransparent dual-electrode hydrogel based triboelectric nanogenerator with tough interfacial bonding and high energy output, Journal Material Chemistry C, 8,5752. Yin R, Tao XM* and Xu BG, 2020. Systematic investigation of twist generation and propagation in a modified ring spinning system, Textile Research Journal, 90(3-4):367-375. Chen A, Tan J, Henry P, Tao XM. 2020. The design and development of ab illuminated polymer optical fiber knitted garment, The Journal of Textile Institute 111(5),745-755. Tao XM*, 2019. Virtual and augmented reality enhanced by touch, Nature, 575(7783): 453-454 Zhou FC, Chen JW, Tao XM, Wang XR, Chai Y, 2019. 2D Materials Based Optoelectronic Memory: Convergence of Electronic Memory and Optical Sensor, Research, 2019, 9490413. Wang Y, Su SC, Cai LA, Qiu BA, Yang CC, Tao XM*, Chai Y*, 2019. Hierarchical supercapacitor electrodes based on metallized glass fiber for ultrahigh areal capacitance, Energy Storage Materials, 20, 315-323. Chen A, Tan J, Tao XM, Henry B, Bai Z, 2019. Changes in knitted E-textiles, Advances in Intelligent Systems and Computing, 849, 129-135. Liu ZY, Zhang ZF, Tam HY, Tao XM*; Multifunctional Smart Optical Fibers: Materials, Fabrication, and Sensing Applications, Photonics, 2019, 6(2), 48. Lin SP, Zeng W, Zhang L, Tao XM*, 2019. Flexible film-based thermoelectric generators, MRS Advances, 4(30),1691-1697. Li, LX, Liu, Su, Tao XM, Song J, 2019. Triboelectric performances of self-powered, ultra-flexible and large-area poly(dimethylsiloxane)/Ag-coated chinlon composites with a sandpaper-assisted surface microstructure, J. Materials Science, 54(10):7823-2833.