廖清,男, 首都师范大学,化学系,教授。
学习/工作经历:
1996年9月-2000年6月 北京大学技术物理系,理学学士;
2002年9月-2007年6月 中国科学院化学研究所,理学博士;
2000年6月-2002年8月 机械表石化通用机械发展中心,职员;
2007年7月-2009年6月 中国科学院化学研究所,光化学系实验室,博士后;
2009年6月-2009年11月 中国科学院化学研究所,光化学系实验室,助理研究员;
2009年11月-2013年1月 中国科学院化学研究所,光化学系实验室,副研究员;
2013年1月-2015年1月 首都师范大学,化学系,副研究员;
2015年1月-至今 首都师范大学,化学系,教授。
学术兼职:
1、分子光子学与激发态化学专业委员会委员。
2、国家自然科学基金委员会项目会评专家。
3、北京市自然科学奖会评专家。
4、北京市基金重点研究专题会评专家。
研究领域:
物理化学、光化学、有机光电功能材料与器件。
承担科研项目情况:
2010年以来,承担科技部重点研发计划课题项目1项(2018YFA0704805),国家自然科学基金委原创探索计划项目1项(22150005)和面上项目5项。
主要业绩:
光子学是研究以光子作为信息和能量载体的科学,涉及到光的产生、传输、操纵和探测等应用技术,由其衍生的光电子材料与器件已经带来了信息、显示等领域的革命性变化。与电子芯片类似,目前光子芯片技术正在从分离式器件向集成光路演进,成为了纳米光子学发展的大趋势和技术前沿。
在光子集成回路中,光子的产生、传输和操控均是以微纳光学材料为载体。有机光子学材料既具有无机半导体的光电性质,又具有分子材料特有的可裁剪性,在光学性能、溶液加工、柔性集成等方面展现出独特优势,是发展新型光子学器件不可或缺的材料基础。尤其是,有机分子通过有序排列形成的聚集体结构,其功能不仅与分子性质相关,还表现出尺寸、形貌及分子排列的依赖性。因此,通过分子结构设计和微纳晶可控制备,可以使电子的局域化效应和分子轨道耦合相互作用的长程效应有机地结合起来,实现对有机微晶材料光子学功能的调控。探索有机微纳晶中光与物质的相互作用机制,实现在微纳尺度上对光子自由度(频率、强度、偏振、相位等)的精准调控,有助于为纳米光子学领域奠定分子材料基础和开拓研究新方向。
申请人以有机微晶材料和激发态过程调控为主线,从分子结构设计出发,抓住分子层次的可控组装关键环节,围绕“产生光子”和“操控光子”这两个纳米光子学的核心科学问题,探索有机微晶在激光光源和拓扑光子器件领域的基础和应用研究。2010年以来,承担科技部重点研发计划课题项目1项(2018YFA0704805),国家自然科学基金委原创探索计划项目1项(22150005)和面上项目5项。在分子光子学微纳材料与器件领域共发表论文100余篇,包括:Nat. Commun. 2篇,Adv. Mater. 8篇,Angew. Chem. Int. Ed. 10篇,J. Am. Chem. Soc. 6篇,Phys. Rev. Lett. 1篇、Nano Lett. 2篇。全部文章SCI它引5千余次,H-index 41。多次被美国化学会C&EN、MaterialsView China等网站作为研究亮点报道。
1、若干低维光功能材料的可控制备及器件研究,付红兵;廖清;徐珍珍;廖奕;姚建年,首都师范大学,2017。
2、有机低维材料的可控制备及光电性能研究,付红兵;廖清;徐珍珍,首都师范大学,2016。
发明公开:
[1]廖博, 付红兵, 宫浩, 廖清. 一种可实现三波段可调谐发射的有机掺杂晶体激光器[P]. 湖南省: CN120810368A, 2025-10-17.
[2]安存彬, 谢倩, 李坤, 廖清, 付红兵. 聚集诱导发光的电子受体材料的制备方法和应用[P]. 北京市: CN120483992A, 2025-08-15.
[3]廖清, 庞艾嘉, 付红兵. 含二苯并噻吩单元的衍生物的合成及其应用[P]. 北京市: CN120463679A, 2025-08-12.
[4]廖清, 张一驰, 赵瑞阳, 付红兵. 联苯乙烯基衍生物分子单晶及基于其的垂直场效应晶体管器件[P]. 北京市: CN120091739A, 2025-06-03.
[5]廖清, 袁世燚, 付红兵. 一种新型组装膜的单发射基彩色窄带有机极化激元发光二极管及其制备方法[P]. 北京市: CN119462398A, 2025-02-18.
[6]徐珍珍, 曹阳阳, 向宇豪, 付红兵, 廖清. 含有五氟化硼单元的衍生物磷光材料的有机发光二极管[P]. 北京市: CN119462716A, 2025-02-18.
[7]廖清, 纪莹, 黄涵, 黎云飞, 付红兵. 一种反芪类衍生物分子的合成、单晶、激光、圆偏振有机发光二极管器件[P]. 北京市: CN118852099A, 2024-10-29.
[8]廖清, 李渊, 黄涵, 安存彬, 李佳钰, 付红兵. 一种基于反式二苯乙烯骨架的有机激光材料、微晶的制备及应用[P]. 北京市: CN118702618A, 2024-09-27.
[9]廖清, 邓一博, 付红兵. 一种基于非手性分子材料,实现自旋谷锁定的圆偏振电致发光的方法[P]. 北京市: CN118632560A, 2024-09-10.
[10]廖清, 朱金龙, 张一驰, 付红兵. 基于液晶光学微腔的发光颜色可调谐的新型高效圆偏振OLEDs[P]. 北京市: CN118068601A, 2024-05-24.
[11]廖清, 朱金龙, 邓一博, 付红兵. 基于光子自旋轨道耦合作用的波长可调的高效圆偏振电致发光器件[P]. 北京市: CN117580428A, 2024-02-20.
[12]付红兵, 李帅, 廖清, 宋仪星. 一种聚集诱导磷光材料、其合成方法及OLED发光器件[P]. 北京市: CN115403599A, 2022-11-29.
[13]廖清, 德健博, 尹璠, 付红兵. 一种有机微腔激子极化激元发光二极管及其制备方法[P]. 北京市: CN115148936A, 2022-10-04.
[14]廖清, 黄涵, 杨柳清, 付红兵. 反芪骨架分子及其合成方法和用途以及有机微腔激子极化激元发光二极管[P]. 北京市: CN115124503A, 2022-09-30.
[15]廖清, 梁倩, 任佳欢, 朱金龙, 龙腾, 付红兵. 微区角分辨庞加莱球的自动化测试装置[P]. 北京市: CN115112572A, 2022-09-27.
[16]廖清, 德健博, 尹璠, 殷海伟, 付红兵. 大面积发光件上电致发光角分辨光谱检测系统及方法[P]. 北京市: CN115112577A, 2022-09-27.
[17]廖清, 梁倩, 付红兵. 微区圆二色谱及圆偏振发光的测试装置[P]. 北京市: CN115046933A, 2022-09-13.
[18]廖清, 尹璠, 付红兵. 基于联苯乙烯基衍生物的低阈值有机固态激光器和高效率的有机发光场效应晶体管[P]. 北京市: CN114957204A, 2022-08-30.
[19]廖清, 付红兵, 龙腾. 一种从有机晶体微腔中的拓扑谷发射的螺旋激子极化激元激光器[P]. 北京市: CN114583533A, 2022-06-03.
[20]廖清, 黄涵, 付红兵. 联苯乙烯基衍生物分子及合成方法、单晶及基于其的有机发光场效应晶体管器件[P]. 北京市: CN113735671A, 2021-12-03.
[21]廖清, 李莉, 吕铮, 满忠伟, 付红兵, 徐珍珍. 一种快速识别羟基自由基的荧光探针及其制备方法和应用[P]. 北京市: CN113461706A, 2021-10-01.
[22]廖清, 吕铮, 李莉, 满忠伟, 付红兵, 徐珍珍. 与淀粉样纤维有高结合力的极性敏感NIR探针及其制备和应用[P]. 北京市: CN113462381A, 2021-10-01.
[23]廖清, 德健博, 尹璠, 付红兵. 大面积发光件上单个像素外量子效率快速检测系统及其检测方法[P]. 北京市: CN113155416A, 2021-07-23.
[24]付红兵, 谢少华, 吴义室, 廖清, 王龙. 具有反芳香性、醌式结构的分子内激子裂分材料的合成方法、薄膜制备方法及单晶制备方法[P]. 北京市: CN113135919A, 2021-07-20.
[25]廖清, 刘鹏, 张秉乾, 付红兵, 徐珍珍. 一种在钙钛矿薄膜表面制备同心环结构的方法[P]. 北京市: CN112279214A, 2021-01-29.
[26]廖清, 满忠伟, 吕铮, 朱金龙, 刘一朗, 刘家鑫, 付红兵, 徐珍珍. 一种STED超分辨成像荧光探针[P]. 北京市: CN111320979A, 2020-06-23.
[27]廖清, 吕铮, 付红兵, 徐珍珍. 一种生物偏振激光探针及其应用[P]. 北京市: CN110384475A, 2019-10-29.
[28]廖清, 杨先凯, 付红兵. 分子内激子裂分材料的合成方法以及薄膜制备方法、单晶制备方法[P]. 北京市: CN110386862A, 2019-10-29.
[29]廖清, 李帅, 于振一, 付红兵. 一种无重金属纯有机室温磷光材料及其合成方法[P]. 北京市: CN110387225A, 2019-10-29.
[30]廖清, 尹璠, 付红兵. 一步法制备多色微纳晶的工艺方法[P]. 北京市: CN110359086A, 2019-10-22.
[31]廖清, 尹璠, 付红兵. 一种可调尺寸制备片状微纳激光器的方法[P]. 北京市: CN110364927A, 2019-10-22.
[32]廖清, 付红兵, 王真. 有机荧光材料及其制备方法以及微晶[P]. 北京市: CN110240588A, 2019-09-17.
[33]廖清, 付红兵, 王真. 新型有机小分子光电材料微纳器件制备方法[P]. 北京市: CN110240589A, 2019-09-17.
[34]廖清, 付红兵, 徐珍珍, 蔡欣, 郑晓霖, 何先雄, 刘鹏, 王真, 张兆仪. 新型有机小分子材料的合成方法、微晶的制备方法及其应用[P]. 北京市: CN110240615A, 2019-09-17.
[35]廖清, 付红兵, 徐珍珍, 蔡欣, 郑晓霖, 何先雄, 刘鹏, 王真, 张兆仪. 一种有机小分子微晶的制备方法[P]. 北京市: CN110240621A, 2019-09-17.
[36]廖清, 任佳欢, 付红兵. 一种有效调控强耦合劈裂能的方法[P]. 北京市: CN110164583A, 2019-08-23.
[37]廖清, 张兆仪, 付红兵. 一种利用软光刻技术制备有机半导体材料环形阵列集成光电器件的方法[P]. 北京市: CN109979876A, 2019-07-05.
[38]廖清, 张兆仪, 付红兵. 新型有机近红外微环阵列光子学器件的制备的方法[P]. 北京市: CN109962407A, 2019-07-02.
[39]廖清, 高庆刚, 付红兵. 一种新型有机半导体激光功率器的设计方法[P]. 北京市: CN109935689A, 2019-06-25.
[40]廖清, 任佳欢, 付红兵. 一种有效调控微腔腔长的方法[P]. 北京市: CN109936045A, 2019-06-25.
[41]廖清, 高庆刚, 付红兵. 一种制备棒状微纳晶激光器的方法[P]. 北京市: CN109936046A, 2019-06-25.
[42]付红兵, 张兆仪, 张海华, 廖清. 利用掩模法制备红绿双色量子点显色阵列系统的方法及新型量子点显示装置[P]. 北京市: CN109768171A, 2019-05-17.
[43]付红兵, 何先雄, 刘鹏, 廖清, 徐珍珍. 一种多色卤素钙钛矿荧光材料的制备方法和应用[P]. 北京: CN106753336A, 2017-05-31.
[44]付红兵, 刘鹏, 何先雄, 廖清, 徐珍珍, 任佳欢. 一种利用溶液限域生长制备光电材料阵列的方法及应用[P]. 北京: CN106653941A, 2017-05-1
发明授权:
[1]付红兵, 李帅, 廖清, 宋仪星. 一种聚集诱导磷光材料、其合成方法及OLED发光器件[P]. 北京市: CN115403599B, 2025-10-17.
[2]付红兵, 廖清, 王智佳, 罗大钊, 赵晨, 赵炫博, 齐芳, 鲁波, 李冰, 卢联合, 宋威. 含有二氧化氯的组合物以及制备二氧化氯片剂的方法[P]. 北京市: CN119366514B, 2025-07-18.
[3]廖清, 德健博, 尹璠, 殷海伟, 付红兵. 大面积发光件上电致发光角分辨光谱检测系统及方法[P]. 北京市: CN115112577B, 2025-05-23.
[4]廖清, 梁倩, 付红兵. 微区圆二色谱及圆偏振发光的测试装置[P]. 北京市: CN115046933B, 2024-04-26.
[5]廖清, 梁倩, 任佳欢, 朱金龙, 龙腾, 付红兵. 微区角分辨庞加莱球的自动化测试装置[P]. 北京市: CN115112572B, 2024-04-26.
[6]廖清, 刘鹏, 张秉乾, 付红兵, 徐珍珍. 一种在钙钛矿薄膜表面制备同心环结构的方法[P]. 北京市: CN112279214B, 2023-12-22.
[7]廖清, 黄涵, 杨柳清, 付红兵. 反芪骨架分子及其合成方法和用途以及有机微腔激子极化激元发光二极管[P]. 北京市: CN115124503B, 2023-04-18.
[8]付红兵, 谢少华, 吴义室, 廖清, 王龙. 具有反芳香性、醌式结构的分子内激子裂分材料的合成方法、薄膜制备方法及单晶制备方法[P]. 北京市: CN113135919B, 2022-05-06.
[9]廖清, 德健博, 殷海玮, 尹璠, 付红兵. 大面积发光件上单个像素外量子效率快速检测系统及其检测方法[P]. 北京市: CN113155416B, 2022-02-25.
[10]廖清, 张兆仪, 付红兵. 一种利用软光刻技术制备有机半导体材料环形阵列集成光电器件的方法[P]. 北京市: CN109979876B, 2021-01-15.
[11]付红兵, 何先雄, 刘鹏, 廖清, 徐珍珍. 一种多色卤素钙钛矿荧光材料的制备方法和应用[P]. 北京市: CN106753336B, 2019-08-06.
[12]付红兵, 刘鹏, 何先雄, 廖清, 徐珍珍, 任佳欢. 一种利用溶液限域生长制备光电材料阵列的方法及应用[P]. 北京市: CN106653941B, 2018-05-08.
发表英文论文:
[1]Wang, Shengdong; Xie, Zhipeng; Zhu, Da; Fu, Shuai; Wu, Yishi; Yu, Hongling; Lu, Chuangye; Zhou, Panke; Bonn, Mischa; Wang, Hai I.; Liao, Qing; Xu, Hong; Chen, Xiong*; Gu, Cheng*.Efficient photocatalytic production of hydrogen peroxide using dispersible and photoactive porous polymers.Nature Communications, 2023, 14(1): 6891.
[2]Man, Zhongwei; Lv, Zheng; Xu, Zhenzhen*; He, Jingping; Liao, Qing; Yang, Yongan; Yao, Jiannian; Fu, Hongbing*.Host Surface-Induced Excitation Wavelength-Dependent Organic Afterglow.Journal of the American Chemical Society, 2023, 145(24): 13392-13399.
[3]Li, Yiming; Li, Yuan; Luo, Xiaoxuan; Guo, Chaowei; Qin, Yuanbin; Fu, Hongbing; Zhang, Yanpeng; Yun, Feng; Liao, Qing*; Li, Feng*.Elimination of Chirality in Three-Dimensionally Confined Open-Access Microcavities.Nanomaterials, 2023, 13(12): 1868.
[4]Liu, Zheng-Fei; Ren, Jiahuan; Li, Pan; Niu, Li-Ya; Liao, Qing*; Zhang, Shaodong*; Yang, Qing-Zheng*.Circularly Polarized Laser Emission from Homochiral Superstructures based on Achiral Molecules with Conformal Flexibility.Angewandte Chemie - International Edition, 2023, 62(2).
[5]Liang, Qian; Ma, Xuekai; Long, Teng; Yao, Jiannian; Liao, Qing*; Fu, Hongbing*.Circularly Polarized Lasing from a Microcavity Filled with Achiral Single-Crystalline Microribbons.Angewandte Chemie - International Edition, 2023, 135(9).
[6]De Jianbo; Ma Xuekai; Yin Fan; Ren Jiahuan; Yao Jiannian; Schumacher Stefan; Liao Qing; Fu Hongbing; Malpuech Guillaume; Solnyshkov Dmitry.Room-Temperature Electrical Field-Enhanced Ultrafast Switch in Organic Microcavity Polariton Condensates.Journal of the American Chemical Society, 2023.
[7]Jia Jichao; Cao Xue; Ma Xuekai; De Jianbo; Yao Jiannian; Schumacher Stefan; Liao Qing; Fu Hongbing.Circularly polarized electroluminescence from a single-crystal organic microcavity light-emitting diode based on photonic spin-orbit interactions.Nature Communications, 2023, 14(1): 31-31.
[8]Liu, Kun; Zhao, Yang; Huang, Han; Zhu, Jinlong; Gu, Chunling; Liao, Qing; Fu, Hongbing*.Homogenous Hyperbranched Networks Enabling Anisotropic Photon Transport and Polarization Filtering.Advanced Optical Materials, 2023.
[9]Yang, Shilin; Liao, Bo*; Liang, Enxiang; Yi, Shoujun; Liao, Qing*.Reversible light-controlled fluorescence switch of block polymer-grafted carbon dots and cellular imaging.Soft Matter, 2022, 18(41): 8017-8023.
[10]Long, Teng; Ma, Xuekai; Ren, Jiahuan; Li, Feng; Liao, Qing*; Schumacher, Stefan; Malpuech, Guillaume; Solnyshkov, Dmitry; Fu, Hongbing.Helical Polariton Lasing from Topological Valleys in an Organic Crystalline Microcavity.Advanced Science, 2022, 9(29): 2203588.
[11]Zhang, Zemin; Vogelbacher, Florian; De, Jianbo; Wang, Yang; Liao, Qing; Tian, Yang; Song, Yanlin; Li, Mingzhu*.Directional Laser from Solution-Grown Grating-Patterned Perovskite Single-Crystal Microdisks.Angewandte Chemie - International Edition, 2022, 61(34): e202205636.
[12]Bolla, Geetha; Guo, Junfeng; Zhao, Huijuan; Lv, Shaokai; Liu, Jie; Li, Yang; Zhen, Yonggang*; Liao, Qing; Wang, Xinran; Fu, Hongbing; Dong, Huanli; Wang, Zongrui; Wang, Zhaohui; Hu, Wenping*.Pyridyl substitution at the 2,6-positions of anthracene toward crystal polymorphs with distinct optical characteristics.CrystEngComm, 2022, 24(32): 5683-5687.
[13]Zhang, Xiangyu; De, Jianbo; Liu, Haichao*; Liao, Qing*; Zhang, Shi-Tong; Zhou, Changjiang; Fu, Hongbing; Yang, Bing*.Cis-Trans Isomerism Inducing Cocrystal Polymorphism with Thermally Activated Delayed Fluorescence and Two-Photon Absorption.Advanced Optical Materials, 2022, 10(16): 2200286.
[14]Man, Zhongwei; Lv, Zheng; Xu, Zhenzhen*; Liu, Meihui; He, Jingping; Liao, Qing; Yao, Jiannian; Peng, Qian; Fu, Hongbing*.Excitation-Wavelength-Dependent Organic Long-Persistent Luminescence Originating from Excited-State Long-Range Proton Transfer.Journal of the American Chemical Society, 2022, 144(28): 12652-12660.
[15]Liu, Kun; Li, Shuai; Fu, Liyuan; Lei, Yilong; Liao, Qing*; Fu, Hongbing*.Cocrystallization tailoring radiative decay pathways for thermally activated delayed fluorescence and room-temperature phosphorescence emission.Nanoscale, 2022, 14(17): 6305-6311.
[16]Man, Zhongwei; Lv, Zheng; Xu, Zhenzhen*; Liao, Qing; Liu, Meihui; Yao, Jiannian; Fu, Hongbing*.Self-Erase Force-Induced Turn-On Organic ASE Output Cryptographic Primitive for Advanced Multiple Information Encryption.Laser & Photonics Reviews, 2022, 16(3): 2100552.
[17]Man Zhongwei; Bao Jinsong; Xu Zhenzhen; Lv Zheng; Liao Qing; Yao Jiannian; Fu Hongbing.Boosting the Efficiency of Organic Solid‐State Lasers by Solvato‐Tailored Assemblies.Advanced Functional Materials, 2022, 32(43).
[18]Liu, Dan; Liao, Qing; Peng, Qian; Gao, Haikuo; Sun, Qi; De, Jianbo; Gao, Can; Miao, Zhagen; Qin, Zhengsheng; Yang, Jiaxin; Fu, Hongbing; Shuai, Zhigang; Dong, Huanli*; Hu, Wenping.High Mobility Organic Lasing Semiconductor with Crystallization-Enhanced Emission for Light-Emitting Transistors.Angewandte Chemie International Edition, 2021, 60(37): 20274-20279.
[19]Liao, Qing*; Leblanc, Charly; Ren, Jiahuan; Li, Feng; Li, Yiming; Solnyshkov, Dmitry; Malpuech, Guillaume; Yao, Jiannian; Fu, Hongbing.Experimental Measurement of the Divergent Quantum Metric of an Exceptional Point.Physical Review Letters, 2021, 127(10): 107402.
[20]Li, Shuai; Fu, Liyuan; Xiao, Xiaoxiao; Geng, Hua; Liao, Qing; Liao, Yi; Fu, Hongbing*.Regulation of Thermally Activated Delayed Fluorescence to Room-Temperature Phosphorescent Emission Channels by Controlling the Excited-States Dynamics via J- and H-Aggregation.Angewandte Chemie International Edition, 2021, 60(33): 18059-18064.
[21]Liu, Peng; Zhang, Bingqian; Liao, Qing*; Tian, Guifen; Gu, Chunling; Fu, Hongbing.Solution-Processed Large-Scale Concentric-Ring Laser on Two-Dimensional Ruddlesden-Popper Perovskites Thin Films.Advanced Optical Materials, 2021, 9(16): 2100193.
[22]Li, Shuai; Jin, Xue; Yu, Zhenyi*; Xiao, Xiaoxiao; Geng, Hua; Liao, Qing; Liao, Yi; Wu, Yishi; Hu, Wenping; Fu, Hongbing*.Design of thermally activated delayed fluorescent emitters for organic solid-state microlasers.Journal of Materials Chemistry C, 2021, 9(23): 7400-7406.
[23]Man, Zhongwei; Cui, Hongtu; Lv, Zheng; Xu, Zhenzhen*; Wu, Zhaoyang; Wu, Yishi; Liao, Qing; Liu, Meihui; Xi, Peng*; Zheng, Lemin*; Fu, Hongbing*.Organic Nanoparticles-Assisted Low-Power STED Nanoscopy.Nano Letters, 2021, 21(8): 3487-3494.
[24]Li, Yuan; Wang, Kai; Liao, Qing*; Fu, Liyuan; Gu, Chunling; Yu, Zhenyi; Fu, Hongbing.Tunable Triplet-Mediated Multicolor Lasing from Nondoped Organic TADF Microcrystals.Nano Letters, 2021, 21(7): 3287-3294.
[25]Solnyshkov, D. D.*; Leblanc, C.; Bessonart, L.; Nalitov, A.; Ren, Jiahuan; Liao, Qing; Li, Feng; Malpuech, G..Quantum metric and wave packets at exceptional points in non-Hermitian systems.Physical Review B, 2021, 103(12): 125302.
[26]Lv, Zheng; Man, Zhongwei; Cui, Hongtu; Xu, Zhenzhen*; Cao, Huanhuan; Li, Shuai; Liao, Qing; He, Qihua; Zheng, Lemin*; Fu, Hongbing*.Red AIE Luminogens with Tunable Organelle Specific Anchoring for Live Cell Dynamic Super Resolution Imaging.Advanced Functional Materials, 2021, 30(10): 2009329.
[27]Han, Xixi; Lei, Yilong*; Liao, Qing*; Fu, Hongbing*.Color- and Dimension-Tunable Light-Harvesting Organic Charge-Transfer Alloys for Controllable Photon-Transport Photonics.Angewandte Chemie International Edition, 2021, 60(6): 3037-3046.
[28]Jiahuan Ren; Qing Liao*; Feng Li*; Yiming Li; Olivier Bleu; Guillaume Malpuech; Jiannian Yao; Hongbing Fu*; Dmitry Solnyshkov*.Nontrivial band geometry in an optically active system.Nature Communications, 2021, 12(1): 689.
[29]Bolla, Geetha#; Liao, Qing#; Amirjalayer, Saeed#; Tu, Zeyi#; Lv, Shaokai; Liu, Jie; Zhang, Shuai; Zhen, Yonggang*; Yi, Yuanping; Liu, Xinfeng; Fu, Hongbing; Fuchs, Harald; Dong, Huanli; Wang, Zhaohui; Hu, Wenping.Cocrystallization Tailoring Multiple Radiative Decay Pathways for Amplified Spontaneous Emission.Angewandte Chemie International Edition, 2021, 60(1): 281-289.
[30]Jiahuan Ren, Qing Liao*, Xuekai Ma*, Stefan Schumacher, Jiannian Yao, and Hongbing Fu, “Realization of Exciton-Mediated Optical Spin-Orbit Interaction in Organic Microcrystalline Resonators”, Laser Photon. Rev. 2100252 (2021).
[31]Yin, Fan; Wang, Long; Yang, Xiankai; Liu, Meihui; Geng, Hua; Liao, Yi; Liao, Qing*; Fu, Hongbing*.High performance single-crystalline organic field-effect transistors based on molecular-modified dibenzo[a,e]pentalenes derivatives.New Journal of Chemistry, 2020, 44(40): 17552-17557.
[32]Ren, Jiahuan; Liao, Qing*; Huang, Han; Li, Yao; Gao, Tingge*; Ma, Xuekai*; Schumacher, Stefan; Yao, Jiannian; Bai, Shuming; Fu, Hongbing*.Efficient Bosonic Condensation of Exciton Polaritons in an H-Aggregate Organic Single-Crystal Microcavity.Nano Letters, 2020, 20(10): 7550-7557.
[33]Feng, Changfu; Li, Shuai; Fu, Liyuan; Xiao, Xiaoxiao; Xu, Zhenzhen; Liao, Qing; Wu, Yishi*; Yao, Jiannian*; Fu, Hongbing*.Breaking Kasha's Rule as a Mechanism for Solution-Phase Room-Temperature Phosphorescence from High-Lying Triplet Excited State.Journal of Physical Chemistry Letters, 2020, 11(19): 8246-8251.
[34]Zhou, Dandan; Zhang, Bingqian; Yu, Zhenyi; Liao, Qing; Fu, Hongbing*.tert-Butyl-substituted bicarbazole as a bipolar host material for efficient green and yellow PhOLEDs.New Journal of Chemistry, 2020, 44(25): 10472-10478.
[35]Jin, Xue; Huang, Han; Wang, Xuedong; Liao, Qing; Hu, Wenping; Fu, Hongbing.Control of molecular packing toward a lateral microresonator for microlaser array.Journal of Materials Chemistry C, 2020, 8(25): 8531-8537.
[36]Qian, Meng-Dan; Sun, Yun-Lu*; Hu, Zhi-Yong; Fang, Xiao-Feng; Zhu, Jin-Long; Fan, Xudong; Liao, Qing; Wu, Chang-Feng*; Sun, Hong-Bo*.Fluorescent chemo-sensors based on "dually smart" optical micro/nano-waveguides lithographically fabricated with AIE composite resins.Materials Horizons, 2020, 7(7): 1782-1789.
[37]Sun Chun-Lin; Li Jun; Song Qi-Wei; Ma Yu; Zhang Ze-Qi; De Jian-Bo; Liao Qing; Fu Hongbing*; Yao Jiannian*; Zhang Hao-Li*.Lasing from an Organic Micro-Helix.Angewandte Chemie International Edition, 2020, 59(27): 11080-11086.
[38]De, Jianbo; Liao, Qing*; Xiao, Xiaoxiao; Liu, Huiying; Chen, Weiben; Chen, Long; Geng, Hua; Liao, Yi; Fu, Hongbing*.Remotely Photocontrolled Microrobots based on Photomechanical Molecular Crystals.ACS Applied Materials & Interfaces, 2020, 12(24): 27493-27498.
[39]Liu, Dan; De, Jianbo; Gao, Haikuo; Ma, Suqian; Ou, Qi; Li, Shuai; Qin, Zhengsheng; Dong, Huanli*; Liao, Qing; Xu, Bin; Peng, Qian; Shuai, Zhigang; Tian, Wenjing; Fu, Hongbing; Zhang, Xiaotao; Zhen, Yonggang; Hu, Wenping.Organic Laser Molecule with High Mobility, High Photoluminescence Quantum Yield, and Deep-Blue Lasing Characteristics.Journal of the American Chemical Society, 2020, 142(13): 6332-6339.
[40]Man, Zhongwei; Lv, Zheng; Xu, Zhenzhen; Liao, Qing; Liu, Jiaxin; Liu, Yilang; Fu, Liyuan; Liu, Meihui; Bai, Shuming; Fu, Hongbing.Highly Sensitive and Easily Recoverable Excitonic Piezochromic Fluorescent Materials for Haptic Sensors and Anti-Counterfeiting Applications.Advanced Functional Materials, 2020, 30(17): 2000105.
[41]Dang, Wei*; Xie, Ningbo; Feng, Changfu; Wang, Ying; Wang, Kai; Liao, Qing; Liang, Baolai; Zhao, Xiaohui*.Electronic excited state energy competition between donor and acceptor in oligo(phenylene vinylene) microcrystal.Optical Materials, 2020, 101: 109714.
[42]Han Huang; Zhenyi Yu*; Dandan Zhou; Shuai Li; Liyuan Fu; Yishi Wu; Chunling Gu*; Liao, Qing; Hongbing Fu*.Wavelength-Turnable Organic Microring Laser Arrays from Thermally Activated Delayed Fluorescent Emitters.ACS Photonics, 2019, 6: 3208−3214.
[43]Feng, Changfu; Li, Shuai; Xiao, Xiaoxiao; Lei, Yilong*; Geng, Hua; Liao, Yi; Liao, Qing; Yao, Jiannian; Wu, Yishi; Fu, Hongbing*.Excited-State Modulation for Controlling Fluorescence and Phosphorescence Pathways toward White-Light Emission.Advanced Optical Materials, 2019, 7(20): 1900767.
[44]Liao, Qing*; Jin, Xue; Fu, Hongbing*.Tunable Halide Perovskites for Miniaturized Solid-State Laser Applications.Advanced Optical Materials, 2019, 7(17): 1900099.
[45]Shuai Li; Zhenyi Yu*; Xiaoxiao Xiao; Hua Geng; Kai Wang; Xue Jin; Liao, Qing; Yi Liao; Yishi Wu; Jiannian Yao; Hongbing Fu*.Modulation of Amplified Spontaneous Emissions between Singlet Fluorescence and Triplet Phosphorescence Channels in Organic Dye Lasers.Laser Photonics Rev., 2019, 1900036.
[46]Wang, Ke; Li, Chang; Li, Zheng; Li, Huizeng; Li, An; Li, Kaixuan; Lai, Xintao; Liao, Qing; Xie, Fang; Li, Mingzhu*; Song, Yanlin.A facile fabrication strategy for anisotropic photonic crystals using deformable spherical nanoparticles.Nanoscale, 2019, 11(30): 14147-14154.
[47]Man, Zhongwei; Lv, Zheng; Xu, Zhenzhen*; Cui, Hongtu; Liao, Qing; Zheng, Lemin*; Jin, Xue; He, Qihua; Fu, Hongbing*.Organic nanoparticles with ultrahigh stimulated emission depletion efficiency for low-power STED nanoscopy.Nanoscale, 2019, 11(27): 12990-12996.
[48]He, Xianxiong; Wang, Yaguang; Li, Kun; Wang, Xi; Liu, Peng; Yang, Yijun; Liao, Qing; Zhai, Tianyou; Yao, Jiannian; Fu, Hongbing*.Oriented Growth of Ultrathin Single Crystals of 2D Ruddlesden-Popper Hybrid Lead Iodide Perovskites for High-Performance Photodetectors.ACS Applied Materials & Interfaces, 2019, 11(17): 15905-15912.
[49]Sun, Chun Lin; Li, Jun; Wang, Xiao Zhen; Shen, Rong; Liu, Sha; Jiang, Jian Qiao; Li, Ting; Song, Qi Wei; Liao, Qing; Fu, Hong Bing*; Yao, Jian Nian*; Zhang, Hao Li*.Rational Design of Organic Probes for Turn-On Two-Photon Excited Fluorescence Imaging and Photodynamic Therapy.Chem, 2019, 5(3): 600-616.
[50]Cai Xin; Xu Zhenzhen*; Zheng Xiaolin; Ran Chenhui; Liu Peng; He Xianxiong; Jin Xue; Liao Qing; Fu Hongbing*.A stimuli-responsive and chemically tunable organic microcrystal laser switch.Chemical Communications, 2019, 55(6): 814-817.
[51]He Xianxiong; Wang Yaguang; Li Kun; Wang Xi; Liu Peng; Yang Yijun; Liao Qing; Zhai Tianyou; Yao Jiannian; Fu Hongbing.Oriented-Growth of Ultrathin Single Crystals of 2D Ruddlesden-Popper Hybrid Lead Iodide Perovskite for High-Performance Photodetectors.ACS Applied Materials & Interfaces, 2019, 11(17).
[52]Zhao Guangyao; Dong Huanli*; Liao Qing; Jiang Jun; Luo Yi; Fu Hongbing; Hu Wenping*.Organic field-effect optical waveguides.Nature Communications, 2018, 9: 4790.
[53]Lv Zheng; Man Zhongwei; Xu Zhenzhen*; Feng Changfu; Yang Yong; Liao Qing; Wang Xu; Zheng Lemin; Fu Hongbing*.Intracellular near-Infrared Microlaser Probes Based on Organic Microsphere-SiO2 Core-Shell Structures for Cell Tagging and Tracking.ACS Applied Materials & Interfaces, 2018, 10(39): 32981-32987.
[54]Zhang Zhaoyi; Wang Zhen; Xu Zhenzhen*; Gao Qinggang; Liu Peng; Ren Jiahuan; Li Meili; Zhou Cong; Liao Qing; Fu Hongbing*.Soft Lithography to Fabricate 3D Patterning Organic Microrings towards High-Performance Near-Infrared Laser Arrays.Advanced Optical Materials, 2018, 6(16): 1800219.
[55]Liao Qing*; Wang Zhen; Gao Qinggang; Zhang Zhaoyi; Ren Jiahuan; De Jianbo; Zhang Xiaosen; Xu Zhenzhen; Fu Hongbing*.The effect of 1D-and 2D-polymorphs on organic single-crystal optoelectronic devices: lasers and field effect transistors.Journal of Materials Chemistry C, 2018, 6(30): 7994-8002.
[56]Huang Ling; Gao Qinggang; Sun Ling Dong*; Dong Hao; Shi Shuo; Cai Tong; Liao Qing*; Yan Chun Hua*.Composition-Graded Cesium Lead Halide Perovskite Nanowires with Tunable Dual-Color Lasing Performance.Advanced Materials, 2018, 30(27): 1800596.
[57]Zhang Haihua; Wu Yishi*; Liao Qing*; Zhang Zhaoyi; Liu Yanping; Gao Qinggang; Liu Peng; Li Meili; Yao Jiannian; Fu Hongbing*.A Two-Dimensional Ruddlesden-Popper Perovskite Nanowire Laser Array based on Ultrafast Light-Harvesting Quantum Wells.Angewandte Chemie International Edition, 2018, 57(26): 7748-7752.
[58]Liao Qing*; Wang Xin Guo; Lv Shaokai; Xu Zhenzhen; Zhang Yi; Fu Hongbing*.Cluster-Mediated Nucleation and Growth of J- and H-Type Polymorphs of Difluoroboron Avobenzone for Organic Microribbon Lasers.ACS Nano, 2018, 12(6): 5359-5367.
[59]Li Meili; Gao Qinggang; Liu Peng; Liao Qing; Zhang Haihua; Yao Jiannian; Hu Wenping; Wu Yishi*; Fu Hongbing*.Amplified Spontaneous Emission Based on 2D Ruddlesden-Popper Perovskites.Advanced Functional Materials, 2018, 28(17): 1707006.
[60]Zhang Haihua; Liao Qing*; Wu Yishi; Zhang Zhaoyi; Gao Qinggang; Liu Peng; Li Meili; Yao Jiannian; Fu Hongbing*2D Ruddlesden-Popper Perovskites Microring Laser Array.Advanced Materials, 2018, 30(15): 1706186.
[61]He, Xianxiong; Liu, Peng; Wu, Suning; Liao, Qing; Yao, Jiannian; Fu, Hongbing*.Multi-color perovskite nanowire lasers through kinetically controlled solution growth followed by gas-phase halide exchange.Journal of Materials Chemistry C, 2017, 5(48): 12707-12713.
[62]Li, Jinbiao; Wu, Yishi; Xu, Zhenzhen; Liao, Qing; Zhang, Haihua; Zhang, Yi; Xiao, Lu; Yao, Jiannian; Fu, Hongbing*.Tuning the organic microcrystal laser wavelength of ESIPT-active compounds via controlling the excited enol* and keto* emissions.Journal of Materials Chemistry C, 2017, 5(46): 12235-12240.
[63]Xu, Zhenzhen*; Zhang, Zhiwei; Jin, Xue; Liao, Qing; Fu, Hongbing*.Polymorph-Dependent Green, Yellow, and Red Emissions of Organic Crystals for Laser Applications.Chemistry-An Asian Journal, 2017, 12(23): 2985-2990.
[64]Zhang, Haihua; Liao, Qing*; Wu, Yishi*; Chen, Jianwei; Gao, Qinggang; Fu, Hongbing*.Pure zero-dimensional Cs4PbBr6 single crystal rhombohedral microdisks with high luminescence and stability.Physical Chemistry Chemical Physics, 2017, 19(43): 29092-29098.
[65]Liu, Peng; He, Xianxiong; Ren, Jiahuan; Liao, Qing; Yao, Jiannian; Fu, Hongbing*.Organic-Inorganic Hybrid Perovskite Nanowire Laser Arrays.ACS Nano, 2017, 11(6): 5766-5773.
[66]Yu, Zhenyi; Wu, Yishi*; Xiao, Lu; Chen, Jianwei; Liao, Qing; Yao, Jiannian; Fu, Hongbing*.Organic Phosphorescence Nanowire Lasers.Journal of the American Chemical Society, 2017, 139(18): 6376-6381.
[67]He, Xianxiong; Liu, Peng; Zhang, Haihua; Liao, Qing*; Yao, Jiannian; Fu, Hongbing*.Patterning Multicolored Microdisk Laser Arrays of Cesium Lead Halide Perovskite.Advanced Materials, 2017, 29(12): 1604510.
[68]Zhang, Yi; Liao, Qing*; Wang, Xinguo; Yao, Jiannian; Fu, Hongbing*.Lattice-Matched Epitaxial Growth of Organic Heterostructures for Integrated Optoelectronic Application.Angewandte Chemie International Edition, 2017, 56(13): 3616-3620.
[69]Zhang, Haihua; Wang, Xu; Liao, Qing; Xu, Zhenzhen; Li, Haiyang; Zheng, Lemin*; Fu, Hongbing*.Embedding Perovskite Nanocrystals into a Polymer Matrix for Tunable Luminescence Probes in Cell Imaging.Advanced Functional Materials, 2017, 27(7): 1604382.
[70]Sun, Chun-Lin; Lv, Shao-Kai; Liu, Yan-Ping; Liao, Qing; Zhang, Hao-Li*; Fu, Hongbing*; Yao, Jiannian*.Benzoindolic squaraine dyes with a large two-photon absorption cross-section.Journal of Materials Chemistry C, 2017, 5(5): 1224-1230.
[71]Liu, Huiying; Wang, Lei; Wu, Yishi*; Liao, Qing*.Luminescence emission-modulated based on specific two-photon compound of triazole-conjugated pyrene derivative.RSC Advances, 2017, 7(31): 19002-19006.
[72]Wang, Shaoxiong; Hu, Xiaochen; Tan, Lulu; Liao, Qing*; Chen, Zhengbo*.Colorimetric detection of lysozyme based on its effect on the growth of gold nanoparticles induced by the reaction of chloroauric acid and hydroxylamine.Microchimica Acta, 2016, 183(12): 3135-3141.
[73]Zhang, Haihua; Liao, Qing*; Wang, Xuedong; Yao, Jiannian; Fu, Hongbing*.Water-Resistant Perovskite Polygonal Microdisks Laser in Flexible Photonics Devices.Advanced Optical Materials, 2016, 4(11): 1718-1725.
[74]Zhang, Haihua; Liao, Qing*; Wang, Xuedong; Hu, Ke; Yao, Jiannian; Fu, Hongbing*.Controlled Substitution of Chlorine for Iodine in Single-Crystal Nanofibers of Mixed Perovskite MAPbI(3-x)Cl(x).Small, 2016, 12(28): 3780-3787.
[75]Haihua, Zhang; Qing, Liao; Xuedong, Wang; Ke, Hu; Jiannian, Yao; Hongbing, Fu.Photodetectors: Controlled Substitution of Chlorine for Iodine in Single-Crystal Nanofibers of Mixed Perovskite MAPbI3-xClx(Small 28/2016).Small, 2016, 12(28): 3880-3880.
[76]Dang, Wei; Liao, Qing; Mao, Peng-Cheng; Fu, Hong-Bing; Weng, Yu-Xiang*.Lasing dynamics study by femtosecond time-resolved fluorescence non-collinear optical parametric amplification spectroscopy.Chinese Physics B, 2016, 25 (05): 223-226.
[77]Zhenyi Yu; Yishi Wu*; Qing Liao; Shuming Bai; Hongbing Fu*.Self-Assembled Microdisk Lasers of Perylenediimides.Journal of the American Chemical Society, 2015, 137(48): 15105-15111.
[78]Chen, Zhengbo*; Zhang, Chenmeng; Gao, Qinggang; Wang, Guo; Tan, Lulu; Liao, Qing*.Colorimetric Signal Amplification Assay for Mercury Ions Based on the Catalysis of Gold Amalgam.Analytical Chemistry, 2015, 87(21): 10963-10968.
[79]Lu, Xiaomei; Wang, Xuedong; Liao, Qing; Fu, Hongbing*.Controlled Self-Assembly of Organic Microcrystals for Laser Applications.Journal of Physical Chemistry C, 2015, 119(38): 22108-22113.
[80]Xuedong Wang; Qing Liao; Shuming Bai; Yishi Wu; Xiaomei Lu; Huaiyuan Hu; Qiang Shi; Hongbing Fu*.Near-Infrared Lasing from Small-Molecule Organic Hemispheres.Journal of the American Chemical Society, 2015, 137(29): 9289-9295.
[81]Qing Liao*; Ke Hu; Haihua Zhang; Xuedong Wang; Jiannian Yao; Hongbing Fu*.Perovskite Microdisk Microlasers Self-Assembled from Solution.Advanced Materials, 2015, 27(22): 3405-3410.
[82]Qing Liao; Xue Jin; Haihua Zhang; Zhenzhen Xu; Jiannian Yao; Hongbing Fu*.An Organic Microlaser Array Based on a Lateral Microcavity of a Single J-aggregation Microbelt.Angewandte Chemie International Edition, 2015, 54(24): 7037-7041.
[83]Shi, Xingrui; Xu, Zhenzhen*; Liao, Qing*; Wu, Yishi; Gu, Zhanjun; Zheng, Renhui; Fu, Hongbing*.Aggregation enhanced two-photon fluorescence of organic nanoparticles.Dyes and Pigments, 2015, 115: 211-217.
[84]Haihua Zhang; Qing Liao*; Xuedong Wang; Zhenzhen Xu; Hongbing Fu*.Self-assembled organic hexagonal micro-prisms with high second harmonic generation efficiency for photonic devices.Nanoscale, 2015, 7(22): 10186-10192.
[85]Sun, Chun-Lin; Liao, Qing; Li, Ting; Li, Jun; Jiang, Jian-Qiao; Xu, Zhen-Zhen; Wang, Xue-Dong; Shen, Rong; Bai, De-Cheng; Wang, Qiang; Zhang, Sheng-Xiang; Fu, Hong-Bing; Zhang, Hao-Li*.Rational design of small indolic squaraine dyes with large two-photon absorption cross section.Chemical Science, 2015, 6(1): 761-769.
[86]Xu, Zhenzhen*; Liao, Qing*; Wang, Xuedong; Fu, Hongbing*.Whispering Gallery Mode Laser Based on a Self-Assembled Organic Octahedron Microcrystal Microresonator.Advanced Optical Materials, 2014, 2(12): 1160-1166.
[87]Wang, Xuedong; Liao, Qing; Lu, Xiaomei; Li, Hui; Xu, Zhenzhen; Fu, Hongbing*.Shape-Engineering of Self-Assembled Organic Single Microcrystal as Optical Microresonator for laser Applications.Scientific Reports, 2014, 4: 7011.
[88]Wang, Xuedong; Liao, Qing*; Kong, Qinghua; Zhang, Yi; Xu, Zhenzhen; Lu, Xiaomei; Fu, Hongbing*.Whispering-Gallery-Mode Microlaser Based on Self-Assembled Organic Single-Crystalline Hexagonal Microdisks.Angewandte Chemie-International Edition, 2014, 53(23): 5863-5867.
[89]Wang, Xuedong; Liao, Qing*; Xu, Zhenzhen; Wu, Yishi; Wei, Lang; Lu, Xiaomei; Fu, Hongbing*.Exciton-Polaritons with Size-Tunable Coupling Strengths in Self-Assembled Organic Microresonators.Acs Photonics, 2014, 1(5): 413-420.
[90]Kong, Qinghua; Liao, Qing*; Xu, Zhenzhen; Wang, Xuedong; Yao, Jiannian; Fu, Hongbing*.Epitaxial Self-assembly of Binary Molecular Components into Branched Nanowire Heterostructures for Photonic Applications.Journal of the American Chemical Society, 2014, 136(6): 2382-2388.
[91]Liao, Qing*; Zhang, Haihua; Zhu, Weigang; Hu, Ke; Fu, Hongbing*.Perylene crystals: tuning optoelectronic properties by dimensional-controlled synthesis.Journal of Materials Chemistry C, 2014, 2(45): 9695-9700.
[92]Sun, Jingsong; Wang, Xiaolei; Liu, Junfeng; Wan, Pengbo; Liao, Qing; Wang, Feng; Luo, Liang*; Sun, Xiaoming.Highly stable Ag-Au nanoplates and nanoframes for two-photon luminescence.RSC Advances, 2014, 4(67): 35263-35267.
[93]Sun, Yan-Qiu; Lei, Yi-Long; Gao, Jing; Sun, Xu-Hui*; Lin, Sheng-Huang; Bao, Qiao-Liang; Liao, Qing*; Lee, Shuit-Tong; Liao, Liang-Sheng*.Two-dimensional optical waveguiding and luminescence vapochromic properties of 8-hydroxyquinoline zinc (Znq(2)) hexagonal microsheets.Chemical Communications, 2014, 50(74): 10812-10814.
[94]Liao, Qing*; Xu, Zhenzhen; Zhong, Xiaolan; Dang, Wei; Shi, Qiang; Zhang, Chao; Weng, Yuxiang; Li, Zhiyuan; Fu, Hongbing*.An organic nanowire waveguide exciton-polariton sub-microlaser and its photonic application.Journal of Materials Chemistry C, 2014, 2(15): 2773-2778.
[95]Liu, Huiying; Cao, Xinqiang; Wu, Yishi*; Liao, Qing; Jimenez, Angel J.; Wuerthner, Frank*; Fu, Hongbing*.Self-assembly of octachloroperylene diimide into 1D rods and 2D plates by manipulating the growth kinetics for waveguide applications.Chemical Communications, 2014, 50(35): 4620-4623.
[96]Feng, Jiao; Bian, Sha; Long, Yue; Yuan, Hao; Liao, Qing; Cai, Huaqiang*; Huang, Hui*; Song, Kai*; Yang, Guoqiang.Low threshold photonic crystal lasing from a dye with high emission quantum yield and weak self-quenching.JOURNAL OF MATERIALS CHEMISTRY C, 2013, 1(38): 6157-6162.
[97]Xu, Zhenzhen; Liao, Qing*; Shi, Xingrui; Li, Hui; Zhang, Haoli; Fu, Hongbing*.Full-color tunable organic nanoparticles with FRET-assisted enhanced two-photon excited fluorescence for bio-imaging.Journal of Materials Chemistry B, 2013, 1(44): 6035-6041.
[98]Gu, Xinggui; Yao, Jingjing; Zhang, Guanxin; Yan, Yongli; Zhang, Chuang; Peng, Qian; Liao, Qing; Wu, Yishi; Xu, Zhenzhen; Zhao, Yongsheng; Fu, Hongbing*; Zhang, Deqing*.Polymorphism-Dependent Emission for Di(p-methoxylphenyl)dibenzofulvene and Analogues: Optical Waveguide/Amplified Spontaneous Emission Behaviors.Advanced Functional Materials, 2012, 22(23): 4862-4872.
[99]Huang, Guangxi; Zhang, Guanxin; Wu, Yishi; Liao, Qing; Fu, Hongbing*; Zhang, Deqing*.Modification of the Green Fluorescent Protein Chromophore with Large Aromatic Moieties: Photophysical Study and Solid-State Emission.ASIAN JOURNAL OF ORGANIC CHEMISTRY, 2012, 1(4): 352-358.
[100]xu zhenzhen#; liao qing#; shi qiang; zhang haoli; yao jiannian; fu hongbing*.Low-Threshold Nanolasers Based on Slab-Nanocrystals of H-Aggregated Organic Semiconductors.Advance Materials, 2012, 24: OP216-OP220.
[101]xu zhenzhen; liao qing; wu yishi; ren wenlu; li wei; liu libing; wang shu; gu zhanjun*; zhang haoli*; fu hongbing*.Water-miscible organic J-aggregate nanoparticles as efficient two-photon fluorescent nano-probes for bio-imaging.J. Mater. Chem., 2012, 22: 17737-17743.
[102]Cao, Xinqiang; Bai, Shuming; Wu, Yishi; Liao, Qing; Shi, Qiang; Fu, Hongbing*; Yao, Jiannian*.Self-assembly of twisted tetrachloroperylenediimide chromophores into two dimensional brick-stone aggregates: exciton dynamics and photoconductivity.Chemical Communications, 2012, 48(51): 6402-6404.
[103]Zhang, Dezhong; Luo, Liang; Liao, Qing; Wang, Hao; Fu, Hongbing*; Yao, Jianniao*.Polypyrrole/ZnS Core/Shell Coaxial Nanowires Prepared by Anodic Aluminum Oxide Template Methods.Journal of Physical Chemistry C, 2011, 115(5): 2360-2365.
[104]Jiang, Zi-Wen; Peng, Ai-Dong; Liao, Qing; Zhao, Yong-Sheng; Yao, Jian-Nian*.Preparation and Optical Properties of One-Dimensional Sub-microstructures of Naphthalene-1,4-dicarbonitrile.Chem. J. Chin. U., 2011, 32(7): 1451-1455.
[105]Jiang, Ji-Dong; Liao, Qing; Zhao, Yong-Sheng*; Yao, Jian-Nian*.Tunable two-photon pumped lasing from alloyed semiconductor nanoribbons.Journal of Materials Chemistry, 2011, 21(13): 4837-4842.
[106]Liao, Qing; Fu, Hong-Bing*; Wang, Chen; Yao, Jian-Nian*.Cooperative Assembly of Binary Molecular Components into Tubular Structures for Multiple Photonic Applications.Angewandte Chemie International Edition, 2011, 50(21): 4942-4946.
[107]Zhao, Yong Sheng; Fu, Hongbing; Peng, Aidong; Ma, Ying; Liao, Qing; Yao, Jiannian*.Construction and Optoelectronic Properties of Organic One-Dimensional Nanostructures.Accounts of Chemical Research, 2010, 43(3): 409-418.
[108]Lei, Yi-Long; Liao, Qing; Fu, Hong-Bing*; Yao, Jian-Nian*.Orange-Blue-Orange Triblock One-Dimensional Heterostructures of Organic Microrods for White-Light Emission.Journal of the American Chemical Society, 2010, 132(6): 1742-1743.
[109]Li, Ming-Zhu; Liao, Qing; Liu, Ye; Li, Zhi-Yuan; Wang, Jing-Xia; Jiang, Lei; Song, Yan-Lin*.A white-lighting LED system with a highly efficient thin luminous film.Applied Physics A-Materials Science & Processing, 2010, 98(1): 85-90.
[110]Huang, Li-Wei; Liao, Qing; Shi, Qiang; Fu, Hong-Bing*; Ma, Jin-Shi; Yao, Jian-Nian*.Rubrene micro-crystals from solution routes: their crystallography, morphology and optical properties.Journal of Materials Chemistry, 2010, 20(1): 159-166.
[111]Gao, Fei; Liao, Qing; Xu, Zhen-Zhen; Yue, Yong-Hao; Wang, Qiang; Zhang, Hao-Li*; Fu, Hong-Bing*.Strong Two-Photon Excited Fluorescence and Stimulated Emission from an Organic Single Crystal of an Oligo(Phenylene Vinylene).Angewandte Chemie International Edition, 2010, 49(4): 732-735.
[112]Liao, Qing; Fu, Hong-Bing*; Yao, Jian-Nian*.Waveguide Modulator by Energy Remote Relay from Binary Organic Crystalline Microtubes.Advanced Materials, 2009, 21(41): 4153-4157.
[113]Zhang, Meng; Zhai, Tian-You; Wang, Xi; Liao, Qing; Ma, Ying*; Yao, Jian-Nian*.Carbon-assisted morphological manipulation of CdS nanostructures and their cathodoluminescence properties.Journal of Solid State Chemistry, 2009, 182(11): 3188-3194.
[114]Lei, Yi-Long; Liao, Qing; Fu, Hong-Bing*; Yao, Jian-Nian*.Phase- and Shape-Controlled Synthesis of Single Crystalline Perylene Nanosheets and Its Optical Properties.Journal of Physical Chemistry C, 2009, 113(23): 10038-10043.
[115]Wang, Zhong-Liang; Ma, Ying*; Zhang, Rui-Li; Peng, Ai-Dong; Liao, Qing; Cao, Zong-Wei; Fu, Hong-Bing; Yao, Jian-Nian*.Reversible Luminescent Switching in a [Eu(SiW10MoO39)(2)](13-)-Agarose Composite Film by Photosensitive Intramolecular Energy Transfer.Advanced Materials, 2009, 21(17): 1737-1741.
[116]Liao, Qing; Mu, Cheng; Xu, Dong-Sheng*; Ai, Xi-Cheng; Yao, Jian-Nian; Zhang, Jian-Ping*.Gold Nanorod Arrays with Good Reproducibility for High-Performance Surface-Enhanced Raman Scattering.Langmuir, 2009, 25(8): 4708-4714.
[117]Zhai, Tian-You; Fang, XiaoSheng; Bando, Yoshio; Liao, Qing; Xu, Xi-Jin; Zeng, Hai-Bo; Ma, Ying*; Yao, Jian-Nian*; Golberg, Dmitri.Morphology-Dependent Stimulated Emission and Field Emission of Ordered CdS Nanostructure Arrays.ACS Nano, 2009, 3(4): 949-959.
[118]Wang, Hao; Liao, Qing; Fu, Hong-Bing*; Zeng, Yi; Jiang, Zi-Wen; Ma, Jin-Shi; Yao, Jian-Nian*.Ir(ppy)(3) phosphorescent microrods and nanowires: promising micro-phosphors.Journal of Materials Chemistry, 2009, 19(1): 89-96.
[119]He, Ben-Qiao; Liao, Qing; Huang, Yong*.Random lasing in a dye doped cholesteric liquid crystal polymer solution.Optical Materials, 2008, 31(2): 375-379.
[120]Li, Man-Yu; Liao, Qing; Zhang, Meng; Ai, Xi-Cheng*; Li, Fu-You*.Surface-enhanced Raman scattering and DFT computational studies of a benzotriazole derivative.Journal of Molecular Structure, 2008, 888(1-3): 2-6.
[121]Li, Ming-Zhu; He, Fang; Liao, Qing; Liu, Jian; Xu, Liang; Jiang, Lei; Song, Yan-Lin*; Wang, Shu*; ZHu, Dao-Ben.Ultrasensitive DNA Detection Using Photonic Crystals.Angewandte Chemie, 2008, 120(38): 7368-7372.
[122]Li, Ming-Zhu; Liao, Qing; Zhang, Jian-Ping; Jiang, Lei; Song, Yan-Lin*; Zhu, Dao-Ben; Chen, Dong; Tang, Fang-Qiong; Wang, Xue-Hua.Energy transfer boosted by photonic crystals with metal film patterns.Applied Physics Letters, 2007, 91(20): 203516.
[123]Liu, Dong-Fang; Xiang, Yan-Juan; Liao, Qing; Zhang, Jian-Ping; Wu, Xiao-Chun; Zhang, Zeng-Xing; Liu, Li-Feng; Ma, Wen-Jun; Shen, Jun; Zhou, Wei-Ya; Xie, Si-Shen*.A simple route to scalable fabrication of perfectly ordered ZnO nanorod arrays.Nanotechnology, 2007, 18(40): 405303.
[124]Liao, Qing; Li, Man-Yu; Hao, Rui; Ai, Xi-Cheng; Zhang, Jian-Ping*; Wang, Yuan*.Surface-enhanced Raman scattering and DFT computational studies of a cyanuric chloride derivative.Vibrational Spectroscopy, 2007, 44(2): 351-356.
[125]Xu, Li-Fen; Liao, Qing; Zhang, Jian-Ping*; Ai, Xi-Cheng; Xu, Dong-Sheng*.Single-crystalline ZnO nanotube arrays on conductive glass substrates by selective disolution of electrodeposited ZnO nanorods.Journal of Physical Chemistry C, 2007, 111(12): 4549-4552.
[126]Liao, Qing; Wang, Yu; Li, Jian-Long; Wu, Kai*; Ai, Xi-Cheng; Zhang, Jian-Ping*.Spatially confined light output of a crystalline zinc oxide nanonet laser.Applied Physics Letters, 2007, 91(4): 041103.
[127]Wang, Yu; Liao, Qing; Lei, Hao; Zhang, Xiao-Ping; Ai, Xi-Cheng; Zhang, Jian-Ping; Wu, Kai*.Interfacial reaction growth: Morphology, composition, and structure control in preparation of crystalline ZnxAlyOz nanonets.Advanced Materials, 2006, 18(7): 943-947.
[128]Xu, LI-Fen; Guo, Yi; Liao, Qing; Zhang, Jian-Ping; Xu, Dong-Sheng*.Morphological control of ZnO nanostructures by electrodeposition.Journal of Physical Chemistry B, 2005, 109(28): 13519-13522.
[129]Li, Meili; Shang, Qiuyu; Li, Chun; Li, Shuai; Liang, Yin; Yu, Wenjin; Wu, Cuncun; Zhao, Liyun; Zhong, Yangguang; Du, Wenna; Wu, Xianxin; Jia, Zhili; Gao, Yan; Chen, Hui; Liu, Xinfeng; Guo, Shaojun; Liao, Qing; Xing, Guichuan; Xiao, Lixin; Zhang, Qing*.High Optical Gain of Solution-Processed Mixed-Cation CsPbBr3 Thin Films towards Enhanced Amplified Spontaneous Emission.Advanced Functional Materials, 2102210.
[130]Lv, Zheng; Man, Zhongwei; Xu, Zhenzhen*; Li, Shuai; Liao, Qing; Fu, Hongbing*.Highly emissive near-infrared solid organic fluorophores for visualization of latent fingerprints based on the powder dusting method.Journal of Materials Chemistry C.
发表中文期刊论文:
[1]龙腾, 李一鸣, 罗筱璇, 廖清, 李峰. 微腔激子极化激元的自旋轨道耦合效应[J]. 中国激光, 2024, 51 (18): 1-14.
[2]朱金龙, 付红兵, 廖清. 基于不同谐振腔结构的有机微腔激光器的研究进展(特邀)[J]. 光子学报, 2024, 53 (05): 85-103.
[3]曹阳阳, 徐珍珍, 廖清, 付红兵. 二氟化硼配合物类功能材料研究进展[J]. 首都师范大学学报(自然科学版), 2024, 45 (03): 25-34.
[4]常子彦, 姚颖芳, 徐珍珍, 廖清, 付红兵. 胰岛素淀粉样纤维的近红外聚集诱导发光荧光探针[J]. 首都师范大学学报(自然科学版), 2024, 45 (03): 15-24.
[5]庞艾嘉, 邓一博, 倪宇轩, 龙腾, 付红兵, 廖清. 有机体系中激子极化激元研究进展[J]. 首都师范大学学报(自然科学版), 2024, 45 (03): 3-14.
[6]尹璠, 德健博, 廖清, 付红兵. 基于联苯衍生物的有机光电功能材料及器件的研究进展[J]. 中国激光, 2023, 50 (01): 81-92.
[7]尹璠; 德健博; 廖清; 付红兵.基于联苯衍生物的有机光电功能材料及其器件的研究进展.中国激光, 2022, 1-27.
[8]王煜; 陈静; 廖清; 孙伟; 厉建龙; 张建平*; 吴凯*.铝热反应法制备双股类螺旋Zn2SnO4单晶纳米带(英文).Acta Physico - Chimica Sinica, 2012, (10): 2500-2506.
[9]姜紫雯; 彭爱东; 廖清; 赵永生; 姚建年.1,4-二氰基萘一维亚微米结构材料的制备及光学性能.高等学校化学学报, 2011, (07): 1451-1455.
会议论文:
[1]廖清. (2020). 有机无机杂化钙钛矿微纳晶激光及激光阵列. (eds.) 中国化学会第二届全国光功能材料青年学者研讨会摘要集 (pp.214). 首都师范大学;
[2]于振一, 廖清, 金雪 & 付红兵. (2018). 有机微纳激光材料及其光物理过程研究. (eds.) 第一届全国光功能材料青年学者研讨会2018摘要集 (pp.20). 天津大学理学院化学系;光功能材料与器件北京市重点实验室首都师范大学化学系;
[3]于振一, 廖清, 金雪, 付红兵 & Wen-Liang Jia. (2017). 有机微纳激光材料及其光物理过程研究. (eds.) 第十五届全国光化学学术讨论会会议论文集 (pp.41-42).
[4]曹鑫强; 吴义室; 廖清; 付红兵; 姚建年.液相化学反应法制备苝酰亚胺微纳结构以及激子动力学研究.中国化学会第28届学术年会第11分会场摘要集, 2012.
[5]于振一; 廖清; 金雪; 付红兵; Wen LiangJia. 有机微纳激光材料及其光物理过程研究.中国化学会光化学专业委员会, 中国,甘肃省,兰州市.
[6]孙艳秋; 雷义龙; 鲍桥梁; 廖清; 孙旭辉; 廖良生.有机单晶微米片二维光波导及气致变色研究.中国化学会.
[7]曹鑫强; 吴义室; 廖清; 付红兵; 姚建年.液相化学反应法制备苝酰亚胺微纳结构以及激子动力学研究.中国化学会, 中国,四川省,成都市.
[8]廖清; 付红兵; 王辰; 姚建年.二元微米管自组装研究及其光学应用.中国化学会, 中国,四川省,成都市.
[9]廖清; 付红兵*; 姚建年*。基于查尔酮衍生物纳米棒的波导开关研究.中国化学会第27届学术年会, 中国, 2010-06-20至2010-06-23.
[10]李明珠; 廖清; 江雷; 宋延林*。无掺杂白光光子晶体薄膜.中国化学会第27届学术年会, 中国, 2010-06-20至2010-06-23.
荣誉奖励:
1、入选2018年北京市长城学者培育计划。
2、2019年北京市百千万人才工程。
3、获2018年北京市科学技术奖三等奖(第二获奖人)。
有机微纳晶激光器件追梦人
—记首都师范大学化学系教授廖清
于有机微纳晶激光材料与器件研究领域,他的脚步无疑是稳健而坚实的。多年来,对学术研究的浓厚兴趣,驱使他一如既往地在有机微纳晶激光领域探索,并沉醉其中。他就是首都师范大学化学系教授廖清。
搞科研,他认真严谨、力求创新;当导师,他民主开放、尚学尚新。在不同的角色中,廖清以深厚的学术功底,精深的研究和敏锐的洞察力,描绘着自己的科研人生。
心向往之,行将必至
1996年,廖清以优异的成绩考入北京大学技术物理系,学习应用化学专业。大学毕业时,由于种种原因,廖清选择了参加工作,可是工作与所学专业根本不搭边,在他看来,这种工作是单调的、重复的,每天无所事事。这不是自己想要的生活,不适合自己,廖清希望有一天能有机会自由地做真正想做的事情。两年后,他考入中科院化学所硕博连读。廖清告诉记者:“起初并没想在科研路上一直走下去,2007年博士出站,面临多个选择,或者去国外申请博士后,或者留在国内,权衡许久,顾及家庭和孩子,最终选择在国内读博士后。”也是2007年,中科院化学所姚建年院士课题组招博士后,廖清幸运地进到该课题组读博士后。化学所学术氛围浓厚,科研条件好,在姚建年院士和付红兵研究员深厚科研功底的影响下,廖清的研究领域由最初的超快激光学研究扩展到有机微纳米材料制备的研究。2009年博士后出站,凭着优秀的学术成果,他留组做助理研究员和副研究员。对化学的浓厚兴趣,让他下定决心从事学术研究。
一直以来,廖清希望开辟属于自己的空间,开展学术研究。在多年的研究过程中,逐渐将有机微纳米材料与激光性能相结合,与两位老师一起,探索出了一条走向有机微纳米激光器件科学前沿的路。一个偶然的机会,廖清听闻首都师范大学化学系正引进人才,在姚建年院士的推荐下,廖清决定去首师大。他告诉记者,首师大化学系学术氛围浓郁,年轻人聚集,在这样一个有蓬勃朝气科研平台上,可以充分地施展自己的工作能力。就这样,廖清到首师大做了副研究员。对廖清来说,进了首师大,如同鱼儿游入了大海,可以自由自在地游弋,他终于可以做自己的事情,实现自己的想法了。他全身心地投入到科研项目中,在教学之余,开始独立地搞自己的“有机微纳米激光器件”课题研究。
拨开云雾见彩虹
随着科技发展的日新月异,光电器件日趋微型化、集成化,微纳激光作为重要光子元器件,展现出良好的应用前景,为获得更小、更廉价、全光谱覆盖的微纳激光器,廖清对有机微纳晶激光展开了研究。
然而,在对有机微纳晶的研究过程中,廖清遇到两大困难:其一,虽然有机材料可以通过分子修饰调控其光学性能,但是高增益有机分子设计缺乏明确的目标向导;其二,如何对有机分子进行可控排布获得高效光学谐振腔,其内在机理尚不清楚。
面对困难,廖清并没有退缩,他迎难而上,从微纳晶激光的设计、微纳结构与性能的内在联系、指导新材料的合成等三个方面着手,展开了研究。美丽的花儿,勇于战胜生存困境,因此搏得了世人的惊羡;挺拔的大树,奋力阻击风雨,因此搏得了人们的感叹。廖清经过不断的观察、分析,终于战胜困难,在有机微纳晶材料与器件研究领域取得了显著的成果。
在高效有机激光增益材料设计方面,基于有机小分子OPV材料设计的基础上,廖清利用弱H-聚集体效应,在大晶体和微纳晶材料中分别实现了受激发射现象,为发展新型有机激光材料开辟了新途径(Angew. Chem. Int. Ed. 2010, 49, 732.(德国应用化学,2015年影响因子11.261)和Adv. Mater. 2012, 24, OP216-OP220(先进材料,2015年影响因子17.493))。
在高效光学微腔设计方面,为设计与优化谐振,基于有机分子DSB,利用简单的自组装方法,设计制备了高效WGM光学谐振腔,廖清获得了多模和单模激光发射(Angew. Chem. Int. Ed. 2014, 53, 5863.)。为了提高WGM光学谐振腔的品质因子,廖清及其团队设计合成了三维结构的WGM谐振腔,并通过谐振腔尺寸调控成功实现了最小有机光泵浦单模激光器(Adv. Opt. Mater. 2014, 2, 1160.)。由此,廖清得出不同的微纳晶形貌和尺寸都将对光学谐振腔的类型和质量有很大影响。为了验证这一想法,廖清在对有机分子HDMAC的研究中,证实了这一想法,与理论计算的结果相吻合。
廖清及其团队在针对微型化相干光源的设计方面的研究,实现了阵列化的激光输出并同时实现具有相似激光性能的多段微纳米激光器。这在很大程度上解决了有机自组装过程中个体样品很难实现性能完全一致的关键科学问题。该成果发表于2015年4月27日国际化学顶级期刊《Angew. Chem. Int. Ed.》上。这也标志着其学术研究达到本领域国际先进水平。
近来,光电材料领域钙钛矿显示了巨大应用潜力。在指导新材料的合成方面,廖清研究团队瞄准这一方向,首次获得了钙钛矿微米片状结构,分别实现了单模和多模的激光发射以及激光波长从525nm到557nm的调控。这一成果为进一步研究钙钛矿这一新兴材料,提供了新的研究思路和方法,标志着首都师范大学化学系学术研究已达到该领域国际先进水平。成果发表于2015年4月23日国际材料顶级期刊《Advance Materials》上,并得到国家科技部“973计划”、国家自然科学基金以及北京市“有机微纳晶态材料与器件研究”知识创新团队等项目资助。
成功源于创新
在廖清看来,成功源于创新,学术研究就是应标新立异、卓尔不群、独树一帜,否则不能算是学术研究。学术只有不断创新,才能保持旺盛的生命力。然而,目前在学术界不正之风有所蔓延,有个别学术研究不再是为了追求新知和创新思想,而是变成了评职称、捞外快的敲门砖。针对这一现状,廖清认为,科研不端行为不仅给国家造成了大量的资金浪费,而且严重破坏以求真务实为基本精神的学术研究规则,更重要的是,它会破坏学术诚信,污染学术环境,阻碍学术进步和科研创新,而且会危及下一代科研人员的诚信观念,进而对整个科研领域的发展产生深远的不良影响。
在人才培养方面,廖清注重创新型人才培养,他强调,师者要时刻反省自己的思想观念和思维方式,而保持思想先进和创新的根本在于学习。他提倡自由型教育法,要求学生根据导师要求,在思考中提出新的想法与创意,而不是完全禁锢学生的思维。
他主张,教师与学生要开展互动交流,学生要自由地展开自己的想法,不断地与教师探讨、求教,在教师与学生之间观点的交流与碰撞中,激发新的创新点。这也是廖清求学时的一点感触。他告诉记者,自己博士期间的研究成果有60%~70%是与导师交流碰撞的结果。在廖清看来,教师与学生之间的交流与碰撞是一种平等对话,通过这种交流与碰撞,找出认为有价值的研究课题。他坚持以教师的思想为主,学生的思想为辅,在师生之间的平等对话与交流中,激发新的想法与创意并不断推进,这是碰撞出新的研究成果的最佳途径。
谈到未来规划,廖清说,在教学上,会坚持沿着国家教育战略方向走下去,努力提高教学质量;在科研上,将更加注重科研成果的实际应用,比如激光检测、激光显示等涉及服务于大众实际生活运用的相关研究。他谦虚地表示,终极的科研目标还太遥远,虽然有些事情不是个人可以掌控的,但只需努力争取便无愧于心。他的下一步目标就是,集聚能量,向着新型光电一体化有机微纳激光发起冲刺。
博观而约取,厚积而薄发。在有机微纳晶激光科学探索的路上,廖清还在坚守着、积淀着、追寻着、收获着……
来源:科学中国人 2016年第4期创新之路
中国科技创新人物云平台暨“互联网+”科技创新人物开放共享平台(简称:中国科技创新人物云平台)免责声明:
1、中国科技创新人物云平台是:“互联网+科技创新人物”的大型云平台,平台主要发挥互联网在生产要素配置中的优化和集成作用,将互联网与科技创新人物的创新成果深度融合于经济社会各领域之中,提升实体经济的创新力和生产力,形成更广泛的以互联网为基础设施和实现工具的经济发展新形态,实现融合创新,为大众创业,万众创新提供智力支持,为产业智能化提供支撑,加快形成经济发展新动能,促进国民经济提质增效升级。
2、中国科技创新人物云平台暨“互联网+”科技创新人物开放共享平台内容来源于互联网,信息都是采用计算机手段与相关数据库信息自动匹配提取数据生成,并不意味着赞同其观点或证实其内容的真实性,如果发现信息存在错误或者偏差,欢迎随时与我们联系,以便进行更新完善。
3、如果您认为本词条还有待完善,请编辑词条。
4、如果发现中国科技创新人物云平台提供的内容有误或转载稿涉及版权等问题,请及时向本站反馈,网站编辑部邮箱:kjcxac@126.com。
5、中国科技创新人物云平台建设中尽最大努力保证数据的真实可靠,但由于一些信息难于确认不可避免产生错误。因此,平台信息仅供参考,对于使用平台信息而引起的任何争议,平台概不承担任何责任。
点击图片查看原图
