Zhiming M. Wang(王志明)，男，1969年10月生于山东。1998年获得中国科学院半导体研究所理学博士学位，随后在德国柏林Paul-Drude-Institute for Solid State Electronics进行为期两年的博士后工作，自2000年至2011年5月在美国University of Arkansas材料研究科学与工程中心工作十余年，现任电子科技大学教授博导、国家计划特聘专家。王志明教授的研究领域是工程与材料科学，他长期从事分子束外延材料与器件研究，代表性研究成果有量子点多层有序自组织，高指数面纳米结构控制和液滴外延技术等，其中纳米自钻孔技术和量子点分子生长开创了半导体量子结构研究的新方向。同时王志明教授还兼任《Nanoscale Research Letters》期刊主编，《Springer Series in Materials Science》和《Lecture Notes in Nanoscale Science and Technology》丛书编辑，并为能源材料纳米系列国际会议的创始人和组织者。

Zhiming M. Wang obtained his Ph.D. in condensed matter physics from the institute of semiconductors, Chinese Academy of Sciences Beijing in 1998. He carried out post-doctoral work in molecular-beam epitaxy and scanning tunneling microscope at Paul-Drude-Institute for solid state electronics Berlin (1998-2000), and was a research associate in the physics department of the University of Arkansas (2000-2007) before joining the Arkansas Institute of Nanoscale Materials Science and Engineering in 2007 where he was a Research Professor until June 2011. Now he is a Professor of National 1000-Talent Program, working in the University of Electronic Science and Technology of China, Chengdu. His research has centered on the structural, optical, and electrical properties of low-dimensional semiconductor nanostructures. He has published more than 160 scientific articles in peer reviewed journals and edited several conference proceedings. He serves on the editorial board of the book series “Lecture Notes in Nanoscale Science and Technology” and “Springer Series in Materials Science” as well as being the journal editor-in-chief of “Nanoscale Research Letters”.

分子束液滴外延生长三维纳米结构，不仅适用于晶格失配同样也适用于晶格匹配材料系统。在高温条件时，这种技术制备的结构具有相对高的光学和电学性能，也表现出丰富多彩的形貌特征，包括量子环，量子点分子，和纳米孔等。这报告将着重介绍高温液滴外延生长技术的最新进展，同时讨论这种技术应用在光电材料领域的前景和挑战。

Droplet epitaxy enables fabrication of three-dimensional nanostructures in both lattice-mismatched and lattice-matched materials system. At high temperatures it offers relative high optical and electric properties and also a rich spectrum of nanostructured morphologies such as quantum rings, quantum-dot molecules, and nanoholes. This presentation will focus on recent developments in high temperature droplet epitaxy and presents the challenge and promise of its application in optoelectronic field.