浙江大学光电科学与工程学院
State key laboratory of modern optical instruments Zhejiang University
浙江大学现代光学仪器国家重点实验室
邱建荣教授研究团队
College of Optical Science and Engineering Zhejiang University
首页>>团队成员>>华南理工大学课题组>>合作研究人员>>彭明营
彭明营教授
一、基本信息
性别:男
籍贯:浙江江山
学历:博士
毕业学校:中科院上海光机所
职称:教授
邮箱:pengmingying@scut.edu.cn
简介:
彭明营,男,1978年生,博士,华南理工大学材料科学与工程学院教授,博士生导师,国家优青获得者。兼任无机系副主任,省教育厅中德光子材料与器件研究中心主任,Royal Society of Chemistry集团 RSC Advances (IF=3.840)杂志 Associate Editor,American Scientific Publishers集团Reviews in Nanoscience & Nanotechnology杂志Associate Editor,美国光学学会Chinese Optics Letters (IF=1.875)期刊Topical Editor,Elsevier出版集团Optical Materials (IF=1.981,2014年36卷11期)杂志Guest Editor,American Scientific Publishers集团Science of Advanced Materials (IF=2.598)杂志Guest Editor,The Optical Society of American集团Optical Materials Express (IF=2.844)杂志Feature Editor,“中国光学”青年编委,中国硅酸盐学会特种玻璃分会理事,中国稀土学会发光专业委员会委员。
2003年毕业于中科院长春应化所,获理学硕士学位;2006年毕业于中科院上海光机所,获工学博士学位;2006-2008年在德国Erlangen-Nuremberg大学Institut für Optik, Information und Photonik工作,任Research Associate,合作导师L.J. Wang教授;2008-2010年,获得DFG科研职位,在德国Erlangen - Nuremberg大学Lehrstuhl für Glas und Keramik工作, 担任Senior Research Associate、Group Leader, 合作导师Wondraczek教授,讲授2008-2009学期本科生与硕士生核心玻璃课程;2010年被聘为华南理工大学教授;2011年入选教育部新世纪优秀人才支持计划;2012年入选华工第一批“杰出人才培养计划”优秀青年学者培养对象,获得第一届广东省杰青;2013年获得国家优青;2014年入选第八批广东省千百十省级培养对象。2015-2016, 法国里昂一大Invited Professor Position。获得2015年度广东省自然科学二等奖。
二、学习工作经历
2010 – 至今,华南理工大学,材料科学与工程学院,教授
2008 – 2010,德国Erlangen - Nuremberg大学Lehrstuhl für Glas und Keramik工作,担任Senior Research Associate、Group Leader, 合作导师Wondraczek教授
2006 – 2008,德国Erlangen-Nuremberg大学Institut für Optik, Information und Photonik,任Research Associate,合作导师L.J. Wang教授
2003/09 – 2006/07,中科院上海光机所,获工学博士学位
2000/09 – 2003/07,中科院长春应化所,获理学硕士学位
三、研究方向
新型光功能材料与器件、超宽带近红外发光铋掺杂激光材料与器件、非正常价态离子激活荧光材料与LED器件
四、获奖荣誉
2011年入选教育部新世纪优秀人才支持计划;
2012年入选华工第一批“杰出人才培养计划”优秀青年学者培养对象,获得第一届广东省杰青;
2013年获得国家优青;
2014年入选第八批广东省千百十省级培养对象;
2015-2016, 法国里昂一大Invited Professor Position;
2015年,获广东省自然科学二等奖
五、代表性成果
(1). M. Peng, Z. Pei,* G. Hong, Q. Su “Study on the reduction of Eu3+ to Eu2+ in Sr4Al14O25: Eu prepared in air atmosphere” Chem. Phys. Lett., 371 (2003) 1. (times cited:127)
(2). M. Peng,* Z. Pei, G. Hong, Q. Su “The reduction of Eu3+ to Eu2+ in BaMgSiO4: Eu prepared in air and the luminescence of BaMgSiO4: Eu2+ phosphor” J. Mater. Chem., 13 (2003) 1202. (times cited:138)
(3). M. Peng,* J. Qiu, D. Chen, X. Meng, X. Jiang, C. Zhu “Bismuth- and aluminum-codoped germanium oxide glasses for super- broadband optical amplification” Opt. Lett., 29 (2004) 1998. (times cited:182)
(4). M. Peng,* J. Qiu, D. Chen, X. Meng, C. Zhu “Super - broadband 1310nm emission from bismuth and tantalum codoped germanium oxide glasses” Opt. Lett., 30 (2005) 2433.(times cited:168)
(5). M. Peng,* J. Qiu, D. Chen, X. Meng, C. Zhu “Broadband infrared luminescence from Li2O-Al2O3-ZnO-SiO2 glasses doped with Bi2O3” Opt. Express, 13 (2005) 6892.
(6). M. Peng,* D. Chen, J. Qiu,* X. Jiang, C. Zhu, “Bismuth-doped zinc aluminosilicate glasses and glass-ceramics with ultra-broadband infrared luminescence” Opt. Mater., 29 (2007) 556.
(7). M. Peng,* L. Wondraczek “Bismuth-doped oxide glasses as potential solar spectral converters and concentrators” J. Mater. Chem., 19 (2009) 627.
(8). M. Peng,* C. Zollfrank, L. Wondraczek,* “Origin of broad NIR photoluminescence in bismuthate glass and Bi-doped glasses at room temperature” J. Phys.: Condens. Matter, 21 (2009) 285106.
(9). M. Peng, B. Sprenger, M. Schmidt, H. Schwefel, L. Wondraczek, “Broadband NIR photoluminescence from Bi-doped Ba2P2O7 crystals: Insights into the nature of NIR-emitting Bismuth centers” Opt. Express, 18 (2010) 12852.
(10). M. Peng, L. Wondraczek, “Photoluminescence of Sr2P2O7:Bi2+ as a red phosphor for additive light generation” Opt. Lett., 35 (2010) 2544.
(11). N. Zhang, J. Qiu*, G. Dong, Z. Yang, Q. Zhang, M. Peng*, “Broadband tunable near infrared emission of Bi-doped composite germanosilicate glasses”, J. Mater. Chem., 22 (2012) 3154.
(12). R. Cao,† M. Peng,†* L. Wondraczek, J. Qiu, “Superbroad near-to-mid-infrared luminescence from Bi53+ in Bi5(AlCl4)3” Opt. Express, 20 (2012) 2562.
(13). Mingying Peng,* Jincheng Lei, Liyi Li, Lothar Wondraczek, Qinyuan Zhang and Jianrong Qiu, “Site-specific reduction of Bi3+ to Bi2+ in bismuth-doped over-stoichiometric barium phosphates”, J. Mater. Chem. C, 1 (2013) 5303-5308.
(14). Fengwen Kang, Xiaobao Yang, Mingying Peng*, Lothar Wondraczek, Zhijun Ma and Jiurong Qiu “Red photoluminescence from Bi3+ and the influence of the oxygen vacancies perturbation in ScVO4 Matrix: a combined experimental and theoretical study”, J. Phys. Chem. C, 118 (2014) 7515-7522.
(15). Yanqi Zhao, Mingying Peng,* Alain Mermet, Jiayu Zheng, Jianrong Qiu, “Precise frequency shift of NIR luminescence from bismuth-doped Ta2O5-GeO2 glass via composition modulation”, J. Mater. Chem. C, 2 (2014) 7830-7835.
(16). Fengwen Kang, Mingying Peng,* Yanqi Zhao, Guoping Dong, Guochao Nie, Weijiang Liang, Shanhui Xu and Jianrong Qiu, “Broadly tuning Bi3+ emission via crystal field modulation in solid solution compound (Y,Lu,Sc)VO4:Bi for ultraviolet converted white LEDs”, J. Mater. Chem. C, 2 (2014) 6068-6076.
(17). Fengwen Kang, Mingying Peng*, Qinyuan Zhang and Jiurong Qiu “Abnormal anti-quenching and controllable multi-transitions of Bi3+ luminescence by temperature involving a yellow-emitting LuVO4:Bi3+ phosphor for ultraviolet converted white LEDs ”, Chem. Eur. J, 20 (2014) 11522-11530.
(18). Fengwen Kang, Yi Zhang and Mingying Peng*, “Controlling the Energy Transfer via Multi Luminescent Centers to Achieve White Light/Tunable Emissions in a Single-Phased X2-Type Y2SiO5:Eu3+,Bi3+ Phosphor For UltravioletConverted LEDs”, Inorg. Chem. 2015, 54,1462-1473.
(19). Pengfei Li, Mingying Peng,* Lothar Wondraczek, Yanqi Zhao, Bruno Viana, “Red to near infrared ultralong lasting luminescence from Mn2+-doped sodium gallium aluminum germanate glasses and (Al,Ga)-albite glass-ceramics”, J. Mater. Chem. C, 2015, 3, 3406-3415.
(20). Mingying Peng,* Xuewen Yin, Peter A. Tanner,* M. G. Brik, and Pengfei Li, “The site occupancy preference, the enhancement mechanism and the thermal resistance of Mn4+ red luminescence in Sr4Al14O25 : Mn4+ for warm WLEDs”, Chem. Mater., 2015, 27, 2938-2945