Welcome Prof. Kai Tao,Zhejiang University, China to be the TPC!
Prof. Kai Tao,Zhejiang University, China
陶凯教授,浙江大学
Kai Tao is a researcher at School of Mechanical Engineering, Zhejiang University and Hangzhou International Science and Technology Innovation Center, Zhejiang University, a selected candidate of National Overseas High-Level Young Talents Program, and Deputy Director of Zhejiang-Israel Joint Laboratory of Self-Assembled Functional Materials; he is mainly engaged in molecular manufacturing, bio-organic (peptide) self-assembly and its functional applications, preparation and performance testing of superstructure and super-assembled materials, design and fabrication of bio-organic optoelectronic (sub)soft devices He is mainly engaged in the research of molecular fabrication, bio-organic (peptide) self-assembly and its functional applications, preparation and performance testing of ultra-structured and ultra-assembled materials, design and fabrication of bio-organic optoelectronic soft devices, device integration, advanced characterization, device mechanism, performance and reliability optimization, and bio-device interaction. Through multidisciplinary intersection, his research work is dedicated to the design and synthesis of bio-organic molecules, self-assembly and characterization regulation, and the design and fabrication of micro and nano devices for bio-device interface interaction. In addition, we are also working on the research of molecular manufacturing to meet the fabrication accuracy of atomic manufacturing, and to achieve the morphology control of micro and nano scale structural parts and expand their application scope, so as to connect with macroscopic biofabrication, bionic manufacturing and surface functional structure manufacturing.
陶凯,浙江大学机械工程学院、浙江大学杭州国际科创中心研究员,国家海外高层次青年人才计划入选者,浙江-以色列自组装功能材料联合实验室副主任;主要从事分子制造、生物有机(肽)自组装及其功能应用、超结构和超组装材料的制备和性能测试、生物有机光电(子)软器件的设计制造、器件集成、先进表征、器件机制、性能与可靠性优化以及生物-器件界面交互等研究。其研究工作致力于通过多学科交叉,希望打通从生物有机分子的设计与合成、自组装与表征调控、面向生物-器件界面交互的微纳器件的设计制造的全贯通;致力于分子制造研究领域,在匹配原子制造满足制造精度的同时,能对微纳尺度的结构件实现形性调控并拓展其应用范围,从而与宏观的生物制造、仿生制造和表面功能结构制造跨介衔接。