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郑海荣
职称/职务: 教授/研究生院常务副院长兼研工部部长
电话: 029-85310352
传真: 029-85310349
电子信箱: hrzheng@snnu.edu.cn
出生年月:
办公地点: 致知楼3107,文汇楼520

教育经历:

08/1999 ~ 05/2003 博士(凝聚态物理) Department of Physics & Astronomy, The UniversityofGeorgia, Athens,Georgia, USA.

08/1997 ~ 08/1999 硕士(凝聚态物理) Department of Physics, Universityof Puerto Rico, Mayaguez, Puerto Rico.

09/1987 ~ 06/1990 硕士(光学),陕西师范大学物理系,中国科学院物理研究所.                                    

09/1980 ~ 07/1984 学士(物理学),陕西师范大学物理系.

 

工作经历:

08/2012 ~ 至今  研究生院常务副院长(兼党委研工部部长), 陕西师范大学

06/2005 ~ 至今  教授、博士生导师. 陕西师范大学物理学与信息技术学院

08/2004 ~ 06/2005 助理教授(Assistant Professor), Department of Physics, Georgia Southern University, Statesboro, Georgia, USA

06/2003 ~ 08/2004 博士后, Department of Physics & Astronomy,TheUniversity ofGeorgia Athens,Georgia,USA

12/2002 ~ 06/2003 博士后, Department of Physics,ClemsonUniversity,Clemson,South Carolina,USA

08/2001 ~ 01/2003 助教(Teaching Assistant),  Department of Physics & Astronomy, The University of Georgia, Athens, Georgia, USA

08/1999 ~ 07/2001 研究助理(Research Assistant), Department of Physics & Astronomy, The University of Georgia, Athens, Georgia, USA

08/1984 ~ 07/1997 助教、讲师、副教授, 陕西师范大学物理系.

 

学术及社会兼职:

 亚洲光谱学会议国际指导委员会委员,《光散射学报》副主编, 《发光学报》编委, 中国物理学会发光分会委员, 中国物理学会光散射专业委员会委员, 等离激元光子学国际委员会委员,第一届等离激元光子学会议国际委员会主席团成员, 陕西师范大学物理学与信息技术学院光学及光学工程专业学科负责人、现代光学研究所所长.

陕西省光学学会副理事长,全国教育专业学位研究生教育指导委员会委员,西安市雁塔区人大代表,陕西省归侨侨眷第七届委员会常务委员。


研究领域:

   激光光谱学,激发态动力学,纳米材料及凝聚态物质的光学性质,表面增强光谱学,表面等离激元光子学。

 

主持项目:  

 国家自然科学基金项目,教育部科学技术研究重点项目,教育部留学回国人员科研项目, 陕西省科技计划项目, 陕西师范大学中央高校基本科研业务费资助重点项目。《近代物理》陕西省高等学校教学团队, 《量子力学》国家双语教学示范课程。

 

讲授课程:

《激光光谱学原理与技术》,《现代光学实验》,《高等量子力学》,《量子力学》,《原子物理学》,《科技英语》,《University Physics 》,《Physics Lab》.

 

主要获奖情况:  

陕西师范大学年度教学标兵,2012-2013

陕西师范大学教学质量优秀奖、教书育人先进个人

陕西省优秀留学回国人员,2009

陕西省高等学校优秀共产党员,2009

陕西高校巾帼建功标兵,2010

宝钢优秀教师奖, 2010

明德优秀教师奖, 2014

陕西省高等教育教学成果二等奖, 2013

陕西省教育厅科学技术成果一等奖, 2014

 

   科研论文:

   [1]  Higher Order Fano Resonances and Electric Field Enhancements in Disk-Ring Plasmonic Nanostructures

        with Double Symmetry Breaking, Plasmonics, DOI 10.1007/s11468-014-9761-9

   [2]  Molecular Resonant Dissociation of Surface-Adsorbed Molecules by Plasmonic Nanoscissors, 

         Nanoscale, 6, (9)  (2014)

   [3]  High-Vacuum tip enhanced Raman spectroscopy, Front. Phys. 8, 1(17-24) 2014. [Cover]

   [4]  Enhanced red upconversion luminescence by codoping Ce3+ in β-NaY(Gd0.4)F4:

        Yb3+/Ho3+ nanocrystals,  Journal of Materials Chemistry C, 2(5327-5334) (2014).

   [5]  Unusual Upconversion Emission from Single NaYF4: Yb3+/Ho3+ Microrod with

         NIR Excitation, Cryst Eng Comm,  16(6697-6706)( 2014).

   [6]  Facile fabrication and upconversion luminescence enhancement of LaF3:Yb3+/Ln3+(Ln= Er, Tm) 

         nanostructures decorated with Ag nanoparticles@SiO2. Nanotechnology. 25 (045603)(2014) .

   [7]  Enhancem-ent and regulation of  fluorescence emission from NaYF4:Yb3+, Er3+ nanocrystals  by

         codoping Mn2+  J. Nanosci. Nanotech, 16 (4139-44146)(2014)

   [8]   Pr3+/Yb3+ Co-Doped β-Phase NaYF4 Microprisms: Controlled Synthesis and Upconversion

         Luminescence, J. Nanosci. Nanotech. 14, 6(4308-4312)  (2014).

   [9]  Plasmon resonances and strong electric field enhancements in side-by-side tangent nanospheroid

         homodimers,  Opt.  Express,  21, (14) (17176-17185)(2013). 

  [10]  Investigation of upconversionand downconversion fluorescence emissions from

          b-NaLn1F4:Yb3+, Ln23+ (Ln1 =Y, Lu; Ln2 = Er, Ho, Tm, Eu)  hexagonal disk

         system. Materials Research Bulletin48(3505–3512) (2013).

  [11]  Surface enhances fluorescence and raman scattering by gold nanoparticle dimmers and trimers,     

         Journal of Applied Physics, 113, 3(033102 -033102-5)(2013).

  [12]  In-situ plasmon-driven chemical reactions revealed by high vacuum tip-enhanced Raman 

         spectroscopy,  Scientific Report, 2 (647) (2012).

  [13]  Fabrication of flower-like silver nanostructure on the Al substrate for surface enhanced

          fluorescence. Appl. Phys. Lett. 100, 051112(1-3) (2012).

  [14] Tip-Enhanced Ultrasens itive Stokes and Anti-Stok es Raman: Spectroscopy in High Vacuum.           

         Plasmonics. 2012, DOI: 10.1007/s11468-012-9426-5

  [15]  Fabrication of flower-like silver nanostructure on the Al substrate for surface enhanced

         fluorescence,   APPLIED PHYSICS LETTERS,100, 051112 (2012)

  [16]  Surface enhanced fluorescence on three dimensional silver nanostructure substrate,        

         JOURNAL OF APPLIED PHYSICS , 111, 093101 (2012)

  [17]  Spectroscopic study of Eu3+doped LaF3 nanoparticles prepared with different PH values,     

         Journal of Nanoscience and Nanotechnology 11,9808-9812(2011).

  [18]  Luminescence enhancement and quenching by codopant ions in lanthanide doped

         fluoride nanocrystals,  Nanotechnology22 (2011) 175702 

  [19]  Fluorescence enhancement of Ln3+ doped nanoparticles,  

          Journal of Luminescence ,131 (2011) 423–428.

   [20] Efficient fluorescence emission and photon conversion of LaOF:Eu3+

         nanocrystals, APPLIED PHYSICS LETTERS, 98, 011907, 2011.

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