【百家大講堂】第243期:膠體半導體納米晶體的化學設計與應用
講座題目:膠體半導體納米晶體的化學設計與應用
We Play with Chemistry to Design Colloidal Semiconductor Nanocrystals
報 告 人:Vladimir Lesnyak
時 間:2019年10月9日(周三)14:30-16:30
地 點:中關村校區(qū)求是樓426會議室
主辦單位:研究生院,、材料學院
報名方式:登錄北京理工大學微信企業(yè)號---第二課堂---課程報名中選擇“【百家大講堂】第243期:膠體半導體納米晶體的化學設計與應用”
【主講人簡介】
Vladimir Lesnyak,現(xiàn)任德累斯頓工業(yè)大學高級研究員,,Vladimir Lesnyak于2005年獲得白俄羅斯國立大學高分子化學博士學位,,2006-2012年在代爾夫特理工大學從事博士后研究,,合作導師為A. Eychmüller教授,2012-2015年在意大利理工學院進行研究,,合作導師為L. Manna教授,。2016年入職德累斯頓工業(yè)大學。Vladimir Lesnyak研究員目前作為Frontiers in Chemistry主編,,ISRN Nanomaterials Journal編委,,已經(jīng)發(fā)表了90多篇論文,包括Chem. Soc. Rev., J. Am. Chem. Soc., ACS Nano, Nano Lett., Nano Today, Adv. Mater., Angew. Chem等,。專利1項,,合著專著3章,他引次數(shù)3700余次,,H因子33,。Vladimir Lesnyak研究員目前的研究方向主要為納米材料的膠體合成調(diào)控,納米材料的物理化學特性以及納米粒子自組裝與多聚物的雜化,。
Vladimir Lesnyak is currently a senior research scientist at Dresden University of Technology.He received his doctor's degree in polymer chemistry from belarusian state university in 2005, and from 2006 to 2012, he did postdoctoral research in Technische Universiteit Delft with professor a. Eychmuller as co-supervisor.From 2012 to 2015 he conducted research in the Istituto Italiano di Tecnologia with professor L. Manna as co-supervisor.He entered Dresden University of Technology at 2016.Vladimir Lesnyak is research topic editor and Editorial board member at Frontiers in Chemistry, ISRN Nanomaterials journal respectively.Up to now, he has published more than 90 papers including Chem. Soc. Rev., J. Am. Chem. Soc., ACS Nano, Nano Lett., Nano Today, Adv. Mater., Angew. Chem and others, 1 patent, 3 book chapters. The papers have already received about 3700 citations,H-index=33.His current research focuses on the regulation of colloidal synthesis of nanomaterials, physical and chemical properties of nanomaterials, self-assembly of nanoparticles and hybridization of polymers.
【講座信息】
膠體半導體納米材料——量子點經(jīng)歷了近十年的研究,,已經(jīng)逐漸走向商業(yè)化。其最重要因素主要為兩點:(1)其具有尺寸依賴的獨特光電性能(2)基于液相合成的簡易方法,?;谏鲜鰞牲c,該類材料吸引了不同領域的的研究者的高度關注,。
本報告主要總結(jié)了不同膠體納米半導體的研究進展,,主要著重于陽離子交換,膠體框架下的摻雜,,等離子共振效應以及與聚合物交聯(lián)達到表面,、光譜的調(diào)控、在太陽能聚光器中的應用以及高性能薄膜的研究。此外,,還將介紹半導體納米晶體作為場效應晶體管的有源元件的潛在應用,。
Colloidal semiconductor nanocrystals (also known as quantum dots) have evolved during last few decades from fundamental theoretical concepts to real commercial products (one of the recent examples is a line-up of Samsung QLED TVs in which quantum dots are employed as color converters) owing to intensive efforts of a plethora of research groups worldwide. These nanomaterials benefit on one hand from their unique size-dependent optoelectronic properties, based on quantum confinement. On the other hand, their solution-based synthesis is an amazingly simple process, which can be realized in nearly any chemistry lab. Both these factors greatly promote investigation of semiconductor nanocrystals making this field truly interdisciplinary, involving chemists, physicists, biologists, material researchers, engineers, to name the main players.
In this talk, our recent work on the colloidal synthesis of different semiconductor nanocrystals will be summarized. Particular attention will be paid to cation exchange reactions, as a convenient method for modifying the chemical composition of inorganic cores as well as to ligand exchange, as an approach to alter their surface. In the framework of the direct colloidal synthesis a novel approach do dope CdSe nanoplatelets with mercury in order to shift their fluorescence to the red and near-infrared region will be presented. Furthermore, integration of fluorescent semiconductor nanocrystals into composites with polymers, which may be used as luminescent solar concentrators, will be discussed. Quite novel and intensively developed aspect of semiconductor nanoparticles, namely localized surface plasmon resonance, will be touched upon on the example of copper chalcogenide nanocrystals with demonstration of electrochemical modulation of their light absorption and assembly into highly conductive thin films. In addition, a potential application of semiconductor nanocrystals as an active component in field-effect transistors will be shown.