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  • 杜朝玲 ( 副教授 )

    的个人主页 http://faculty.nuaa.edu.cn/dcl/zh_CN/index.htm

  •   副教授   硕士生导师
  • 招生学科专业:
    物理学 -- 【招收硕士研究生】 -- 物理学院
    电子信息 -- 【招收硕士研究生】 -- 物理学院
个人简介

以下信息由研究生系统导入,请酌情修改完善

以第一作者或通讯作者发表学术SCI论文40余篇。

 2007年5月毕业于南京大学物理系,获得理学博士学位;

2007年5至2009年9月:新加坡南洋理工大学从事研究员工作。

2009年9月至今:南京航空航天大学理学院应用物理系从事教学和科研工作。

研究方向:

学科研究方向一:凝聚态物理

微纳光子学,研究贵金属纳米颗粒或阵列的光学及光伏特性。

学科研究方向二:光学

拉曼光谱学,研究基于贵金属纳米颗粒,半导体等介质材料的拉曼效应以及各种增强拉曼效应。

学科研究方向三:光学工程

光电功能材料的设计与性能表征,设计不同光电等性能优异的新型微纳器件。

发表学术论文,出版专著情况:

主要论文列表:


(1) Adjustment of eccentricity and split angle for improved SERS and refractive index sensing of TiN nanodonutsPhysica Scripta,2023,9:045019.

(2) Individual Split Au Square Nanorings for Surface-Enhanced Raman and Hyper-Raman Scattering, Plasmonics, 2022,17:965-971.

(3) Eccentricity improved plasmon refractive index sensing and SERS performances of Au nano-donuts,Physics Letters A, 2022, 443 :12817.

(4) Enhanced photocurrent of perovskite solar cells by a layer of randomly-distributed-Ag-nanospheres, Physics Letters A, 2021, 414 :127620.

(5) Optimal aspect ratio and excitation spectral region of individual AuxAg1−x alloy nanobars for plasmonic sensing, Physics Letters A, 2020, 384126785.

(6) Improved optical properties of perovskite solar cells by introducing Ag nanopartices and ITO AR layersScientific Reports, 2021, 11, 14550.

(7) Optical optimization of ultra-thin crystalline silicon solar cells by a co-simulation approach of FEM and GA, Applied Physics A, 2021, 127, 558.

(8) Plasmonic properties of individual heterogeneous dimers of Au and In nanospheres, Physics Letters A, 2021391, 127137.

(9) Plasmon nanoparticle effect to improve optical properties of perovskite thin film,PNFAP, 2021, 43, 100888.

(10)Individual split Au square nanorings for surface enhanced Raman and hyper-Raman scattering,Plasmonics (accepted).

(11)The cross-section shape-dependent responses of S and FOM of individual Au nanorod sensors, Appl. Phys. A-Mate Sci & Proc , 2019, 125(5):345.

(12) Optimal geometry parameter for plasmonic sensitivities of individual Au nanopoarticle sensors, Physical Chemistry Chemical Physics, 21 (14): 7654-7660.

(13)Plasmonic Coupling Effects on the Refractive Index Sensitivities of Plane Au-Nanosphere-Cluster Sensors, Plasmonics 2018, 13(5): 1729-1734.

(14)Nano-thick-dielectric encapsulation effects on the refractive-index sensitivities of Ag plane-nanosphere-cluster sensors, MPLB, 2018, 32 (8): 1850080.

(15)Geometry and near-field coupling effects on the refractive-index sensitivities of individual Ag nanoparticle sensors Appl. Phys. A 2017, 123 (11): 672.   

(16)Plasmon Peak Sensitivity Investigation of Individual Cu and Cu@Cu2O Core-Shell Nanoparticle Sensors, Plasmonics 2016, 11 (5): 1197-1200

(17)Refractive index sensitivities of plane Ag nanosphere cluster sensors [J]. Sensors and Actuators B: Chemical, 2015, 215: 142-145.

(18)Linear or quadratic plasmon peak sensitivities for individual Au/Ag nanosphere sensors [J], Sensors and Actuators B: Chemical, 2014, 203: 812-816.

(19)Dielectric Nanocup Coating Effect on the Resonant Optical Properties of Individual Au Nanosphere, Plasmonics, 8 (2013) 1523-1527.

(20)Shi, Surface-Enhanced Raman Scattering from Individual Au Nanoparticles on Au Films, Plasmonics, 7 (2012) 475-478.

(21)Enhancement of Raman scattering by individual dielectric microspheres, Journal of Raman Spectrascopy. 45 (2011) 145-148.

(22)Numerically investigating the enhanced Raman scattering performance of individual Ag nanowire tips, APPLIED OPTICS, 50 (2011) 4922-4926.  

(23)Polarized SERS study of an individual Ag nanowire with bulb humps, Optics Communics. 284 (2011) 5844-5846.

(24)Individual Ag Nanowire Dimer for Surface-Enhanced Raman Scattering, Plasmonics, 6 (2011) 761-766.

(25)Near-field coupling effect between individual Au nanospheres and their supporting SiO2/Si substrate, Plasmonics 5 (2009) 105-109.

(26)Polarization-dependent confocal photoluminescence imaging of Ag nanorods and nanoparticles, Plasmonics, 4 (2009) 217-222.

(27)Individual polymer-encapsulated Ag nanoparticles for Surface enhanced Raman scattering, Chemical Physics Letters, 473 (2009) 317-320.

(28) Confocal white light reflection imaging for characterization of metal nanostructures, Optics Communications, 281 (2008) 5360-5363.

(29) Resonant Raman spectroscopy of (Mn,Co)-codoped ZnO films, Journal of Applied Physics, 103 (2008) 023501.

(30) Raman spectroscopy of (Mn,Co)-codoped ZnO films, Journal of Applied Physics, 99 (2006) 123515.

(31) Raman study of anharmonic phonons in SrBiTi4O15 thin films. Journal of Applied Physics, 99 (2006) 094101.

(32) Raman spectroscopic study of ceramic Sr2Bi4Ti5O18, Chinese Physics, 15 (2006) 854.

(33) An empirical formula approach to total cross sections for electron scattering on polyatomic molecules, Chinese Physics Letters, 22 (2005) 2801 .

(34) Composition-dependent structures and properties of Bi4Ti3-xZrxO12 ceramics, Physica B: Condensed Matter, 368 (2005) 157.

(35) Additivity rule for electron scattering on hydrocarbon molecules – considering two different shielding effects, Chinese Physics, 13 (2004) 1418.

(36) Total cross sections for electron scattering on polyatomic molecules – considering two different shielding effects, Physics Letters A, 314 (2003) 150.

(37) Site-selective localization of analytes on gold nanorod surface for investigating field enhancement distribution in surface-enhanced Raman scattering, Nanoscale, 3 (2011) 1575-1581.

(38) Near field optical properties of individual Ag nanowire dimers encapsulated by dielectric layers, BIOTECHNOLOGY, CHEMICAL AND MATERIALS ENGINEERING, PTS: Advanced Materials Research   393-395 (2012) 193-196.

(39) Quan YuanYunfei ZhangYan ChenRuowen WangChaoling DuEmir YasunWeihong Tan, Using silver nanowire antennas to enhance the conversion efficiency of photoresponsive DNA nanomotorsProceedings of the National Academy of Sciences of the United States of America, 2011, 108(23): 9331-9336.

(40) YuMeng You, NA Purnawirman, HaiLong Hu, Kasim J,Huanping YangChaoLing Du, Ting Tu, ZeXiang Shen,Tip-enhanced Raman spectroscopy using single-crystalline Ag nanowire as tipJournal of Raman Spectroscopy 2010, 41(10): 1156-1162.

承担的科研项目情况:

主持并结题国家自然基金(青年基金)1项,国家博士后基金1项,江苏省博士后基金1项,留学回国基金1项。目前,以第二参与人参与国家自然基金1项,主持理工融合项目基金2项。

指导研究生情况:

已有5名研究生以优异成绩毕业,其中2人读博。目前,在读研究生5名。

备注:

欢迎对微纳光电功能材料感兴趣的同学,请联系cldu@nuaa.edu.cn,电话15250995186,或通过QQ群:805355458详询。

教育经历
  • 1994.9 -- 1997.7

    河南南阳市二中       普通高中毕业

  • 2001.9 -- 2004.7

    河南师范大学       原子与分子物理       硕士研究生毕业       理学硕士学位

  • 2001.9 -- 2004.7

    河南师范大学       原子与分子物理       硕士研究生毕业       理学硕士学位

  • 1997.9 -- 2001.7

    河南师范大学       物理学教育       大学本科毕业       理学学士学位

  • 2004.9 -- 2007.6

    南京大学       凝聚态物理       博士研究生毕业       理学博士学位

工作经历
  • 2007.5 -- 2009.8

    南洋理工大学应用物理系

  • 2009.8 -- 至今

    南京航空航天大学理学院

研究方向
  • [1]光学,具体包括光电热功能材料的设计与性能表征,设计不同光电热等性能优异的新型微纳米元器件。
  • [2]凝聚态物理 微纳光子学,研究贵金属纳米颗粒或阵列的光学及光伏、光热特性。
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