人物經歷
1983年,彭笑剛考入吉林大學化學系高分子化學專業。
1987年,本科畢業獲得學士學位,之後在吉林大學化學系,就讀物理化學專業碩士研究生,師從李鐵津教授和沈家驄院士。
1990年,碩士研究生畢業後繼續師從李鐵津教授和沈家驄院士,攻讀博士學位。
1992年,獲得吉林大學化學系物理化學專業博士學位。
1994年,前往美國加州大學伯克利分校,師從Alivisatos教授進行博士後研究工作(至1996年)。
1996年,進入加州大學勞倫斯伯克利國家實驗室工作(至1999年)。
1999年,進入美國阿肯色大學化學和生物化學系任教,先後擔任助理教授(1999年-2003年)、副教授(2003年-2005年)、教授、查爾斯-克麗蒂俠露化學講座教授(2005年-2009年)。
2009年,辭去阿肯色大學教職,全職加盟浙江大學化學系,擔任教授、博士生導師。同年年底以彭笑剛的專利轉化成果為核心創建的杭州納晶科技有限公司成立,獲得風險投資5300萬元。
2011年2月10日,專業信息供應商湯森路透公司(Thomson Reuters)發布了依據過去10年中所發表研究論文的影響因子而確定的全球頂尖一百名化學家榜單(TOP 100 CHEMISTS, 2000-2010),彭笑剛名列第8,在這一百位入選化學家中,彭笑剛是唯一一位在中國國內全職任教的學者 。
主要成就
科研成就
•科研綜述
2001年以來,彭笑剛發展了在學術界和工業界廣為採用的量子點合成化學,不僅引領了國際學術界相關領域的研究,而且奠定了正在快速產業化的量子點電視的化學基礎 。
•學術論著
截至2018年,彭笑剛在《Nature》,《Nature Materials》,《 J. Am. Chem. Soc.》,《Nano Lett.》,《 Angew. Chem. Int. Ed. 》等國際刊物上發表高水平研究論文100餘篇,被引用超過10000餘次,其中論文“Shape control of CdSe nanocrystals: from dots to rods and back” 在《Nature》發表後,被引用超過3000餘次 。
出版著作
出版日期 | 名稱 | 作者 | 出版社 |
2012.10 | 《物理化學講義》 | 彭笑剛著 | 北京:高等教育出版社 |
2015.02 | 《大學與伊甸園 理性教育與人性發展》 | 彭笑剛著 | 北京:清華大學出版社 |
期刊論文
Xing Lin#, Xingliang Dai#, Chaodan Pu#, Yunzhou Deng, Yuan Niu, Limin Tong, Wei Fang*, Yizheng Jin*, and Xiaogang Peng*. Near-optimal-Antibunching, Electrically-driven, and Room-temperature Single-photon Sources Based on Colloidal Quantum Dots. Nature Communications. 2017, 8, 1132.
Maowei Jiang, Xiaogang Peng*, Anisotropic Fe3O4/Mn3O4 Hybrid Nanocrystals with Unique Magnetic Properties , Nano Letters, 2017, 17 (6), 3570-3575.
Haiyan Qin, Renyang Meng, Na Wang, Xiaogang Peng*, Photoluminescence Intermittency and Photo-Bleaching of Single Colloidal Quantum Dot, Advanced Materials, 2017, 29 (14), 1606923.
Xingliang Dai, Yunzhou Deng, Xiaogang Peng , Yizheng Jin*, Quantum-Dot Light-Emitting Diodes for Large-Area Displays: Towards the Dawn of Commercialization, Advanced Materials, 2017, 29 (14), 1607022.
Yang Li, Chaodan Pu, Xiaogang Peng*, Surface Activation of Colloidal Indium Phosphide Nanocrystals, Nano Research, 2017, 10 (3), 941-958.
Wanzhen Lin, Yuan Niu, Renyang Meng, Lin Huang, Hujia Cao, Zhenxing Zhang, Haiyan Qin, Xiaogang Peng*, Shell-thickness Dependent Optical Properties of CdSe/CdS Core/Shell Nanocrystals Coated with Thiol Ligands, Nano Research, 2016, 9 (1), 260-271.
Chaodan Pu, Xiaogang Peng*, To Battle Surface Traps on CdSe/CdS Core/Shell Nanocrystals: Shell Isolation versus Surface Treatment, Journal of the American Chemical Society, 2016, 138 (26), 8134-8142.
Yu Yang, Haiyan Qin, Xiaogang Peng*, Intramolecular Entropy and Size-Dependent Solution Properties of Nanocrystal-Ligands Complexes, Nano Letters, 2016, 16 (4), 2127-2132.
Dongdong Chen, Yuan Gao, Yiya Chen, Yang Ren, Xiaogang Peng*, Structure Identification of Two-Dimensional Colloidal Semiconductor Nanocrystals with Atomic Flat Basal Planes, Nano Letters, 2015, 15 (7), 4477-4482.
Xingliang Dai, Zhenxing Zhang, Yizheng Jin*, Yuan Niu, Hujia Cao, Xiaoyong Liang, Liwei Chen, Jianpu Wang, Xiaogang Peng*, Solution-processed, High-performance Light-emitting Diodes based on Quantum Dots, Nature, 2014, 515 (7525), 96-99.
Yuan Gao, Xiaogang Peng*, Crystal Structure Control of CdSe Nanocrystals in Growth and Nucleation: Dominating Effects of Surface versus Interior Structure, Journal of the American Chemical Society, 2014, 136 (18), 6724-6732.
Zheng Li, Haiyan Qin, Dorel Guzun, Mourad Benamara, Gregory Salamo, Xiaogang Peng*, Uniform Thickness and Colloidal-Stable CdS Quantum Disks with Tunable Thickness: Synthesis and Properties, Nano Research, 5 (5) (2012), 337-351.
Zheng Li, Xiaogang Peng*, Size/Shape-Controlled Synthesis of Colloidal CdSe Quantum Disks: Ligand and Temperature Effects, Journal of the American Chemical Society, 133 (17) (2011), 6578-6586.
Xiaogang Peng*, Band Gap and Composition Engineering on a Nanocrystal (BCEN) in Solution, Accounts of Chemical Research, 43 (11) (2010), 1387-1395.
Xiaogang Peng*, An Essay on Synthetic Chemistry of Colloidal Nanocrystals, Nano Research, 2 (6) (2009), 425-447.
Renguo Xie, Zheng Li, Xiaogang Peng*, Nucleation Kinetics vs Chemical Kinetics in the Initial Formation of Semiconductor Nanocrystals, Journal of the American Chemical Society, 131 (42) (2009), 15457-15466.
Ranjani Viswanatha, David M. Battaglia, Mark E. Curtis, Tetsuya D. Mishima, Matthew B. Johnson, Xiaogang Peng*, Shape Control of Doped Semiconductor Nanocrystals (d-Dots), Nano Research, 1 (2) (2008), 138-144.
Renguo Xie, Xiaogang Peng*, Synthetic Scheme for High-quality InAs Nanocrystals based on Self-focusing and One-pot Synthesis of InAs-based Core-shell Nanocrystals, Angewandte Chemie-International Edition, 47 (40) (2008), 7677-7680.
Narayan Pradhan, Xiaogang Peng*, Efficient and Color-tunable Mn-doped ZnSe Nanocrystal Emitters: Control of Optical Performance via Greener Synthetic Chemistry, Journal of the American Chemical Society, 129 (11) (2007), 3339-3347.
Renguo Xie, David Battaglia, Xiaogang Peng*, Colloidal InP Nanocrystals as Efficient Emitters Covering Blue to Near-infrared, Journal of the American Chemical Society, 129 (50) (2007), 15432-15433.
Xiaogang Peng*, University Spin-offs: Opportunity or Challenge?, Nature Materials, 5 (12) (2006), 923-925.
Narayan Pradhan*, Huifang Xu, Xiaogang Peng*, Colloidal CdSe Quantum Wires by Oriented Attachment, Nano Letters, 6 (4) (2006), 720-724.
David Battaglia, Bridgette Blackman, Xiaogang Peng*, Coupled and Decoupled Dual Quantum Systems in One Semiconductor Nanocrystal, Journal of the American Chemical Society, 127 (31) (2005), 10889-10897.
Nikhil R. Jana, Yongfen Chen, Xiaogang Peng*, Size- and Shape-Controlled Magnetic (Cr, Mn, Fe, Co, Ni) Oxide Nanocrystals via a Simple and General Approach, Chemistry of Materials, 16 (20) (2004), 3931-3935.
Linsong Li, Narayan Pradhan, Yunjun Wang, Xiaogang Peng*, High Quality ZnSe and ZnS Nanocrystals Formed by Activating Zinc Carboxylate Precursors, Nano Letters, 4 (11) (2004), 2261-2264.
Lianhua Qu, W. William Yu, Xiaogang Peng*, In Situ Observation of the Nucleation and Growth of CdSe Nanocrystals, Nano Letters, 4 (3) (2004), 465-469.
Nikhil R. Jana, Xiaogang Peng*, Single-phase and Gram-scale Routes toward Nearly Monodisperse Au and Other Noble Metal Nanocrystals, Journal of the American Chemical Society, 125 (47) (2003), 14280-14281.
Amjad Y. Nazzal, Lianhua Qu, Xiaogang Peng*, Min Xiao*, Photoactivated CdSe Nanocrystals as Nanosensors for Gases, Nano Letters, 3 (6) (2003), 819-822.
Xiaogang Peng*, Mechanisms for the Shape-Control and Shape-Evolution of Colloidal Semiconductor Nanocrystals, Advanced Materials, 15 (5) (2003), 459-463.
Xiaogang Peng*, Green Chemical Approaches toward High-quality Semiconductor Nanocrystals, Chemistry-a European Journal, 8 (2) (2002), 335-339.
Lianhua Qu, Xiaogang Peng*, Control of Photoluminescence Properties of CdSe Nanocrystals in Growth, Journal of the American Chemical Society, 124 (9) (2002), 2049-2055.
Y. Andrew Wang, J. Jack Li, Haiyan Chen, Xiaogang Peng*, Stabilization of Inorganic Nanocrystals by Organic Dendrons, Journal of the American Chemical Society, 124 (10) (2002), 2293-2298.
David Battaglia, Xiaogang Peng*, Formation of High Quality InP and InAs Nanocrystals in a Noncoordinating Solvent, Nano Letters, 2 (9) (2002), 1027-1030.
Jose Aldana, Y. Andrew Wang, Xiaogang Peng*, Photochemical Instability of CdSe Nanocrystals Coated by Hydrophilic Thiols, Journal of the American Chemical Society, 123 (36) (2001), 8844-8850.
Z. Adam Peng, Xiaogang Peng*, Formation of High-quality CdTe, CdSe, and CdS Nanocrystals Using CdO as Precursor, Journal of the American Chemical Society, 123 (1) (2001), 183-184.
Z. Adam Peng, Xiaogang Peng*, Mechanisms of the Shape Evolution of CdSe Nanocrystals, Journal of the American Chemical Society, 123 (7) (2001), 1389-1395.
Xiaogang Peng, Liberto Manna, Weidong Yang, Juanita Wickham, Erik Scher, Andreas Kadavanich, A. P. Alivisatos*, Shape Control of CdSe Nanocrystals, Nature, 404 (6773) (2000), 59-61.
Xiaogang Peng , J. Wickham, A. P. Alivisatos*, Kinetics of II-VI and III-V Colloidal Semiconductor Nanocrystal Growth: "Focusing"of Size Distributions, Journal of the American Chemical Society, 120 (21) (1998), 5343-5344.
Xiaogang Peng , Troy E. Wilson, A. Paul Alivisatos*, Peter G. Schultz*, Synthesis and Isolation of a Homodimer of Cadmium Selenide Nanocrystals, Angewandte Chemie-International Edition in English, 36 (1-2) (1997), 145-147.
A. Paul Alivisatos*, Kai P. Johnsson, Xiaogang Peng*, Troy E. Wilson, Collin J. Loweth, Marcel P. Bruchez Jr, Peter G. Schultz, Organization of Nanocrystal Molecules Using DNA, Nature, 382 (6592) (1996), 609-611.
Xiaogang Peng*, Ran Lu, Yingying Zhao, Lianhua Qu, Haiyan Chen, Tiejin Li*, Control of Distance and Size of Inorganic Nanoparticles by Organic Matrices in Ordered LB Monolayers, The Journal of Physical Chemistry, 98 (28) (1994), 7052-7055.
Xiaogang Peng , Manlai Gao, Yingying Zhao, Shihai Kang, Yunhang Zhang, Yan Zhang, Dejun Wang, Liangzhi Xiao, Tiejin Li*, Preparation of Nanoparticulate Fe2O3-Polymaleic Monoester Alternating Langmuir-Blodgett Films with Functional Organic Hydrophobic Part Chemical Physics Letters, 209 (3) (1993), 233-237.
Xiaogang Peng, Quan Wei, Yueshun Jiang, Xiandong Chai, Tiejin Li*, Jiachong Shen*, X-ray Photoelectron Spectroscopy of Nonstoichiometric Lead Sulfide Monolayers in Stearic Acid Langmuir-Blodgett Films, Thin Solid Films, 210 (1-2) (1992), 401-403.
Xiaogang Peng*, Yan Zhang, Jun Yang, Bingsuo Zou, Liangzhi Xiao, Tiejin Li*, Formation of Nanoparticulate Fe2O3-Stearate Multilayer through the Langmuir-Blodgett Method, The Journal of Physical Chemistry, 96 (8) (1992), 3412-3415.
Xiaogang Peng, Shiquan Guan, Xiangdong Chai, Yueshun Jiang, Tiejin Li*, Preparation and Structure of Q-state Lead Sulfide Monolayers in Metastable Stearic Acid Langmuir-Blodgett Films, The Journal of Physical Chemistry, 96 (7) (1992), 3170-3174.
•專利授權
專利號 | 專利名稱 |
CN103904178B | 量子點發光器件 |
US8658065B2 | Colloidal semiconductor nanocrystals having 1-dimensional quantum confinement and methods of making the same |
US9260652B2 | Metal doped semiconductor nanocrystals and methods of making the same |
US8900481B2 | Monodisperse core/shell and other complex structured nanocrystals and methods of preparing the same |
US9340726B2 | Monodisperse core/shell and other complex structured nanocrystals and methods of preparing the same |
US7919012B2 | Monodisperse core/shell and other complex structured nanocrystals and methods of preparing the same |
US8012377B2 | Doped semiconductor nanocrystals and methods of making same |
US8007757B2 | Multi-dimensional complex nanocrystal structures and methods of making same |
US7632428B2 | Doped semiconductor nanocrystals and methods of making same |
US7531149B2 | Synthetic control of metal oxide nanocrystal sizes and shapes |
US7160525B1 | Monodisperse noble metal nanocrystals |
US7767260B2 | Monodisperse core/shell and other complex structured nanocrystals and methods of preparing the same |
EP1590171B1 | Monodisperse nanokristalle mit kern/schale und anderen komplexen strukturen sowie herstellungsverfahren dafür |
US7273904B2 | Nanocrystals in ligand boxes exhibiting enhanced chemical, photochemical, and thermal stability, and methods of making the same |
US6869545B2 | Colloidal nanocrystals with high photoluminescence quantum yields and methods of preparing the same |
US7105051B2 | High quality colloidal nanocrystals and methods of preparing the same in non-coordinating solvents |
EP1412563B1 | Verfahren zur herstellung von kolloidale nanokristalle in nicht koordinierenden lösungsmitteln |
JP4344613B2 | High quality colloidal nanocrystals and methods of preparation of the same in non-coordinating solvents |
EP1402089B1 | Herstellung von stabilen kolloidalen nanokristallen unter verwendung von organischen dendrons |
US7153703B2 | Synthesis of stable colloidal nanocrystals using organic dendrons |
EP2256834B1 | Kolloidale metallische chalcogenide Nanokristalle |
EP1337695B1 | Synthese von kolloidalen metal chalcogenide nanokristallen |
US6872249B2 | Synthesis of colloidal nanocrystals |
US6225198B1 | Process for forming shaped group II-VI semiconductor nanocrystals, and product formed using process |
US6306736B1 | Process for forming shaped group III-V semiconductor nanocrystals, and product formed using process |
•承擔項目
截至2017年10月,彭笑剛主持和參與多項國家重點研發計畫項目、國家自然科學基金重大和重點項目 。
時間 | 項目名稱 | 項目來源 |
2017/10-2020/09 | 納米晶表面化學與物理:表面結構、動力學、 及其物化性質的關聯性研究 | 國家自然科學基金國際(地區)合作與交流項目, 170萬元,主持 |
2016/7- 2021/6 | 量子點發光顯示關鍵材料與器件研究 | 國家重點研發計畫,6000萬元,主持 |
2015/01- 2018/12 | 高性能、低成本新型量子點發光二極體的研究 | 國家自然科學基金重大項目,350萬,主持 |
2014/01-2016/12 | 基於摻雜量子點的量子點單顆粒螢光閃爍機理研究 | 國家自然科學基金青年基金,25萬元,參與 |
2013/01-2011/12 | 核-殼界面構造與量子點光學性質單分散 | 國家自然科學基金重點項目,300萬元,主持 |
•學術交流
時間 | 地點 | 會議名稱 | 備註 |
2018.9 | 固安 | 2018中國顯示學術會議 | 邀請報告 |
2018.8 | 北京 | 菁華島津科技論壇 | |
2018.7 | 美國 | Gordon Research Conferences (GRC) | 邀請報告 |
2017.10 | 韓國 | 韓國三星電子會議 | |
2017.9 | 台灣 | 2017年國際顯示製程前瞻技術研討會(IDMC’17) | |
2017.5 | 美國 | Society for Information Display | |
2017.4 | 北京 | 2017年國際量子點顯示產業論壇 | 高端對話 |
2016.9 | 南京 | 2016新材料國際發展趨勢高層論壇 | 邀請報告 |
2016.7 | 太原 | EL2016 | 邀請報告 |
2016.7 | 成都 | 科學出版社化學與資源環境分社 | |
2016.5 | 韓國 | The 9th international conference for quantum dots | 邀請報告 |
2016.5 | 舊金山 | SID's Display Week 2016 | 邀請報告 |
2016.4 | 南京 | 介觀化學教育部重點實驗室第三屆學術委員會第一次會議 | |
2016.3 | 美國 | American Physical Society | 邀請報告 |
2016.1 | 廣州 | 《面向能源的光電轉換材料》重大研究計畫學術交流會暨重點支持項目中期檢查會 | |
2015.11 | 韓國 | Pioneer Nano Seoul Forum 2015 (PNSF2015) | 邀請報告 |
2015.10 | 南京 | 第九屆全國暨華人有機分子和聚合物發光學術會議暨第一屆有機電子學術會議 | |
2015.9 | 上海 | 2015新材料國際發展論壇會議 | 邀請報告 |
2015.6 | 武漢 | 第十屆中美華人納米論壇 | 邀請報告 |
2015.3 | 舊金山 | 美國量子點論壇 | 邀請報告 |
2015.1 | 武漢 | 2014年度重大研究計畫年度交流會 | |
2014.8 | 美國 | American Chemical Society | 邀請報告 |
2014.7 | 天津 | 第九屆中美華人納米論壇 | 邀請報告 |
2013.6 | 杭州 | 第八屆中美華人納米論壇 | |
2012.6 | 廈門 | 第七屆中美華人納米論壇 | 邀請報告 |
•科研成果獎勵
時間 | 項目名稱 | 獎勵名稱 |
2014年度 | 利用溶液法製備出高性能量子點發光二極體 | 中國科學十大進展 |
2014年度 | 基於溶液工藝高效量子點發光二極體 | 中國雷射雜誌社“2014中國光學重要成果” |
人才培養
•講授課程
2009年彭笑剛回國後開始集中精力撰寫《物理化學講義》本科生教程,並擔當浙江大學該門本科生基礎課的主講教師,之後他還承擔化學系《物理化學I》、《物理化學II》、《物理化學III》的教學任務 。
•制度建設
彭笑剛還參與浙江大學化學系制度建設,致力於推動學科整體水平提高,2012年浙江大學化學系在《 J. Am. Chem. Soc.》《 Angew. Chem. Int. Ed. 》等國際核心期刊上發表論文30餘篇,較往年發表論文水平有了提高 。
•教學成果獎勵
彭笑剛被評為2013年度浙江大學竺可楨學院最佳任課老師,並獲得浙江大學理學部第四屆本科教學優秀獎 。
榮譽表彰
時間 | 榮譽表彰 | 來源 |
2015年 | 全國先進工作者 | |
2014年 | 湯森路透中國引文桂冠獎最具國際引文影響力獎 |
社會任職
彭笑剛擔任介觀化學教育部重點實驗室第三屆學術委員會委員 。
人物評價
彭笑剛發展了在學術界和工業界廣為採用的量子點合成化學,不僅引領了國際學術界相關領域的研究,而且奠定了正在快速產業化的量子點電視的化學基礎 。 (湖南大學評)