张耀举-温州大学数理与电子信息工程学院

1、张耀举教师简介、个人基本情况:姓 名：张耀举性 别：男出生年月：I960年7月民 族：汉族职称职务：温州大学激光与光电子技术研究所所长电气数字化设计技术国家地方联合工程实验室副主任政治面貌：中国民主同盟最后学历：研究生最高学位：博士工作单位：数理与电子信息工程学院通信地址：温州大学南校区1A111室邮政编码：325035电 话：0577- 86689293E-Mail: zhangyj;从事研究的专业领域及主要研究方向研究的专业领域：微纳光学结构与器件，太阳能电池设计与制备主要研究方向：硅基太阳能电池，太阳能电池减反膜，微纳结构及其制备，光学信息处理从大学开始填写)三、主要工作经历 浙江省二级

2、教授。 主要经历如下：1978年 10 月1981年 7 月 1985年 9月1987年 7 月 1987年 9 月1990年 6 月 2009年 7月2009年 12月 2010年1月 1990年 7月2001年 7月 2001年 8月目前 1999年 11月2004年 10 月 2004年 11月至今开封师范专科学校物理学专科生 河南师范大学物理学本科生 河南师范大学理论物理硕士研究生，硕士 日本熊本大学高访研究学者 获日本熊本大学工学光学工程博士学位 郑州轻工业学院教师温州大学教师副教授教授四、近年来主持的主要科研项目(1) 双面晶硅太阳能电池陷光结构的设计和制备 , 温州市科技项目，

3、2019.01-2020.12(2) 宽波段高效率深刻蚀圆形聚焦光栅及其在太阳电池中的应用研究 (61377021), 国家自然科学基金项目 , 2014.1-2017.12(3) 俘获两类不同折射率粒子的光镊原理与实验研究(No. 61078023), 国家自然科学基金项目 , 2008.1.1-2010.12.30(4) 固体浸没透镜新的设计和制作方法及其应用研究 (60777005), 国家 自然科学基金项目 , 2008.1.1-2010.12.30(5) 深刻蚀圆形石英光栅及其应用研究( No. 2010C31051 ), 浙江省公益性技术应用研究计划项目， 2011.1.1-201

4、2.12.30五、近年完成的主要教学科研成果目录 (含论文、课题、科研获奖、教学成果)1、近几年以第一作者和通讯作者发表部分论文：(1) Cylindrical lens array concentrator with a nanonipple-array antireflective surface for improving the performances of solar cells, Optics Communications, 2019(2) Simple fabrication of nanogratings using flexible polydimethylsiloxane

5、 film, Japanese Journal of Applied Physics, 2019(3) Theoretical analysis of improved efficiency of silicon-wafer solar cells with textured nanotriangular grating structure, Optics Communications, 2018,Vol.410, Issue 1, page:369 -75(4) Application of millimeter-sized polymer cylindrical lens array co

6、ncentrators in solar cells, Chinese Physics B, 2018,Vol.27, Issue 5, page: 058801(5) Multiscale array antireflective coatings for improving efficiencies of solar cells, Applied Surface Science, 2018,Vol.462, Issue 31, page: 105-111(6) Antireflective Paraboloidal Microlens Film for Boosting Power Con

7、version Efficiency of Solar Cells, ACS Applied Materials & Interfaces, 2018, Vol.10, Issue 26, page: 21950-21956(7) A compact and high-power silicon-wafer solar strip-cells-array module integrated with an array concentrator, Chinese Physics B, 2018,Vol.27, Issue 1, page: 018802(8) Enhancement of

8、 silicon-wafer solar cell efficiency with low-cost wrinkle antireflection coating of polydimethylsiloxane, Solar Energy Materials and Solar Cells, 2018,Vol.181, page: 15-20(9) Diffraction in a stratified region of a high numerical aperture Fresnel zone plate: a simple and rigorous integral represent

9、ation, Opt. Express, 2015,Vol.23, Issue 6, page: 8051-8060(10) Diffraction theory of high numerical aperture subwavelength circular binary phase Fresnel zone plate, Optics Express, 2014,Vol.22, Issue 22, page: 27425-27436(11) Effect of the shadowing in high-numerical-aperture binary phase Fresnel zo

10、ne plates, Optics Communications, 2014,Vol.317, Issue 317, page: 88-92(12) Analysis of nearfield subwavelength focusing of hybrid amplitude-phase Fresnel zone plates under radially polarized illumination, Journal of Optics, 2014,Vol.16, Issue 1, page: 015703-6(13) 3D Super-resolution fluorescence mi

11、croscopy using cylindrical vector beams, Progress In Electromagnetics Research Letters, 2013,Vol.43, page: 73-81(14) Periodic transmission of circular binary Fresnel zone plates with etching depth and substrate,Progress In Electromagnetics Research Letters, 2013,Vol.40, page: 93-105(15) Optimizing t

12、he optical field distribution of near-field SIL optical storage system using five-zone binary phase filters, Optics Communications, 2012,Vol.285, Issue 13-14, page: 3042-3045(16) Multifocal optical trapping using counter-propagating radially-polarized beams, Optics Communications. 2012,Vol.285, Issu

13、e 5, page: 725-730(17) Trapping Rayleigh Particles Using Highly Focused Higher-order Radially Polarized Beams, Optics Communications, 2011,Vol.284, Issue 7, page:1734-1739(18) Generation of three-dimensional dark spots with a perfect light shell with a radially polarizedLaguerre -Gaussian beam, Appl

14、ied Optics, 2010,Vol.49, Issue 32, page:6217-6223(19) Symmetry properties of three-dimensional magnetization distributions induced by focused circularly polarized lights, Optik, 2010, Vol.121, Issue 22, page: 2062 -2066(20) Longer axial trap distance and larger radial trap stiffness using a double-r

15、ing radially polarized beam, Optics Letters, 2010, Vol. 35, Issue 8, page:1281-1283(21) Near-fielddouble-spot photolithography with subwavelength spacing, OpticsCommunications, 2010,Vol. 283, Issue 15, pages: 3022-3025(22) Trapping two types of particles using a double-ring-shaped radially polarized

16、 beam, Physical Review A, 2010,Vol.81, Issue 2, page: 023831-5(23) Magnetic field distribution of a highly focused radially-polarized light beam, Optics Express, 2009,Vol.17, Issue 24, page:22235-22239(24) Improving Recording Density of All-Optical Magnetic Storage by Using High-Pass Angular Spectru

17、m Filters, Chin. Phys. Lett., 2009,Vol. 26, Issue 10, page:108501-3(25) Large negative Goos-Hanchen shift from a wedge-shaped thin film, Chin. Opt. Lett., 2009,Vol.7, Issue 9, page:845-848(26) Theoretical study of optical recording with a solid immersion lens illuminated by focused double-ring-shape

18、d radially polarized beam, Optics Communications, 2009, Vol.282, Issue 23, page:4481-4485(27) Dispersion effect in optical microscopy systems with a supersphere solid immersion lens, Chinese Physics B, 2009,Vol. 18, Issue 7, page:2788-2793(28) All-optical magnetic superresolution with binary pupil f

19、ilters, J. Opt. Soc. Am. B, 2009,Vol.26, Issue 7, page:1379-1383(29) Improving the recording ability of a near-field optical storage system by higher-order radially polarized beams, Opt. Express, 2009,Vol.17, Issue 5, 2009, page:3698-3706(30) Theoretical study on all-optical magnetic recording using

20、 a solid immersion lens, J. Opt. Soc. Am. B, 2009,Vol. 26, Issue 7, page:176-182(31) Simple and high efficient optical trapping using a cylindrical lens and a single plane wave of incidence, Opt. Commun., 2008,Vol.281, Issue 19, page:4824-4828(32) High-density all-optical magnetic recording using a

21、high-NA lens illuminated by circularly polarized pulse lights, Physics Letters A, 2008 ,Vol.372, Issue 41, page:6294-6297(33) Giant positive and negative lateral shifts from the Kretschmann-Raether configuration with aweakly absorbing left-handed slab, Physics Letters A, 2008,Vol.372, Issue 41, page:6294-62972、获奖情况：(1) 海岛/岸基大功率特种电源系统关键技术与成套装备及应用，2017 年中国机械工业联合会特等奖，主要参加2008 年温州市科技进步三等奖(2) 温州市第八届师德楷模先进个人，温州市人民政府， 2018 年(3) 低压塑壳断