报告题目：General and Robust Strategies for Nanocrystals with Precisely Controlled Dimensions, Composition, and Architectures for Energy Applications

报 告 人 ：林志群教授

报告时间：2017年7月10日（周一）上午10:00

报告地点：化学楼二楼一号会议室

邀 请 人 ：朱锦涛教授

报告人简介：

林志群教授，1972年出生于福建，本科、硕士、博士分别毕业于厦门大学(1995)、复旦大学(1998)和美国马萨诸塞大学安姆斯特分校(2003)，先后工作于美国伊利诺伊大学厄巴纳-香槟分校(2002-2004)、爱荷华州立大学(2004-2011)和佐治亚理工学院(2011- )。林教授主要从事高分子纳米复合材料、纳米结构功能材料与新能源电池材料的设计合成、结构调控、性能优化及其应用研究。林教授是国际著名材料学家、英国皇家化学会会士、美国杰青、美国物理学会 Frank J. Padden Jr.奖获得者、Journal of Materials Chemistry A副主编和Nanoscale编委。迄今组织/担任国际学术会议/分会主席40余次；应邀在国际会议或科研院所作学术报告170多场。已经发表SCI论文200多篇，其中以通讯/第一作者在Science (1)、Nature Nanotechnology (1)、Nature Communications (1)、Science Advance (1)、Angewandte Chemie International Edition (21)、Journal of the American Chemical Society (5)、Advanced Materials (7)、Nano Letters (5)、Energy & Environmental Science (6)和ACS Nano (6)等IF>10的TOP期刊发表论文60余篇，期刊封面论文41篇，Hot、ESI和VIP论文40余篇；论文被引10000多次，H-index为58；主编学术专著3部。

报告内容：

    Nanocrystals exhibit a wide range of unique properties (e.g., electrical, optical, and optoelectronic) that depend sensitively on their size and shape, and are of both fundamental and practical interest. Breakthrough strategies that will facilitate the design and synthesis of a large diversity of nanocrystals with different properties and controllable size and shape in a simple and convenient manner are of key importance in revolutionarily advancing the use of nanocrystals for a myriad of applications in lightweight structural materials, optics, electronics, photonics, optoelctronics, magnetic technologies, sensory materials and devices, catalysis, drug delivery, biotechnology, and among other emerging fields. In this talk, I will elaborate two general and robust strategies for crafting a large variety of functional 0D and 1D nanocrystals with precisely controlled dimensions (i.e., plain, core/shell and hollow nanoparticles; plain and core/shell nanorods; nanotubes) by capitalizing on a set of rationally designed unimolecular star-like and bottlebrush-like block copolymers, respectively, as nanoreactors. These two strategies are effective and able to produce oil-soluble and water-soluble monodisperse nanoparticles and nanorods, including metallic, ferroelectric, magnetic, luminescent, semiconductor, perovskite, and their core/shell structures, which represent a few examples of the kind of nanocrystals that can be produced using these techniques. The applications of these functional nanocrystals in energy conversion and storage (e.g., dye-sensitized solar cells, perovskite solar cells, thermoelectrics, etc.) will also be discussed.