杨雷
时间:2024-04-06 17:12 来源: 作者: 点击:次
基本信息 杨雷,中国科学院固体物理研究所博士,湖南大学引进人才,湖南大学材料科学与工程学院材料物理与化学系副教授,擅长于纳米材料的制备、包覆和改性、表征分析、功能化和应用。来湖南大学后,主要承担本科生和研究生的《固体物理》、《计算机在材料科学中的应用》、《材料物理基础》和《工程材料物理基础》等课程的教学工作。 教育背景教育背景 2014.9-2014.12 美国亚利桑大州立大学电子、计算与能源学院 访问学者2007.04-2010.03 湖南大学材料科学与工程学院 博士后 2005.07-2008.01 湖南大学材料科学与工程学院 讲师2000.07-2005.07 中国科学院合肥固体研究院固体物理所 博士 导师:张立德 工作履历工作履历 2008.01-今 湖南大学材料科学与工程学院 副教授 研究领域研究概况 近几年先后主持了国家自然科学基金、湖南省自然科学基金、教育部博士点基金新教师基金、博士后科学基金和横向项目等多项项目。发表SCI论文三十多篇。主持的科研项目[1] 稀土掺杂同轴纳米电缆的控制合成技术与可调光学性能研究,国家自然科学基金,基金号11104066[2] 高目度、活性重质碳酸钙制备工艺研究,湖南省自然科学基金常德联合项目重点项目,基金号2013JJ8004[3] 氧化物同轴纳米多层管的合成及其光学性能的研究,高等学校博士学科点专项科研基金,基金号20070532043[4] 同轴纳米电缆阵列显示屏的关键制备技术及显示性能的研究,博士后科学基金,基金号20080431020[5] 一维纳米阵列材料的可控合成及光学性能,中央高校专项基金,基金号531107040172[6] 超细钴、铜粉的制备及工艺研究,横向协作项目,南通新玮镍钴科技发展有限公司,基金号:20109148283[7] 碳酸钙的改性研究与应用,横向协作项目,常德磊鑫科技有限公司,基金号:20109148403[8] 碳酸钙改性研究与应用,横向协作项目,湖南磊鑫新材料科技有限公司,基金号:201491480662参与的科研项目[1] 新型高导热、低膨胀、轻质碳纳米管增强铜基复合材料的制备及其热传导,国家自然科学基金, 基金号:20080148003[2] 微波辐照无烟煤制备超级电容器准一维碳纳米材料的研究,湖南省自然科学基金,基金号:20073148221[3] 新型高导热、低膨胀、轻质铜基电子封装材料研究,省科技厅,基金号:20083348102 学术成果学术成果 代表性科研论文第一作者论文[1] Lei Yang, Zhongcheng Jiang. Blue-shift of Ultraviolet Luminescence in Rough Surfaced ZnO Nanotubes Embedded in the AAO Template, Journal of Nano Research, 2017, 45: 175–184[2] Lei Yang, Zhongcheng Jiang, Jiazhang Dong, Liuqian Zhang, Anlian Pan, Xiujuan Zhuang, Two-step excitation structure changes of luminescence centers and strong tunable blue emission on surface of silica nanospheres, Journal of Nanoparticle Research, 2015, 17(10): 390(1–8)[3] Lei Yang, Jiazhang Dong, Zhongcheng Jiang, Anlian Pan, Xiujuan Zhuang. Visible light stimulating dual-wavelength emission and O vacancy involved energy transfer behavior in luminescence for coaxial nanocable arrays, Journal of Applied Physics, 2014, 115(22), 224308 (1–4)[4] Lei Yang, Zhongcheng Jiang, Jiazhang Dong, Anlian Pan, Xiujuan Zhuang. The study on crystal defects-involved energy transfer process of Eu3+ doped ZnO lattice, Materials Letters, 2014, 129: 65–67[5] Lei Yang, Jiazhang Dong, Yajuan She, Zhongcheng Jiang, Lide Zhang, Hongbin Yu. Self-purification construction of interstitial O in the neighbor of Eu3+ ions to act as energy transfer bridge, Applied Physics Letters, 2014, 104 (3): 033109 (1–5)[6] Lei Yang, Dongpo Su, Yajuan She, Jiazhang Dong, Aiping Hu. The surface luminescence of silica nanospheres depending on different excitation wavelengths and accompanied photochemical reactions, Journal of Nanoparticle Research, 2013, 15 (12):2113 (1–9)[7] Lei Yang, Yajuan She, Wei Zhang, Yutao Chen, Yuanhong Tang, Shihua Zhao, Aiping Hu, Qian Wang, Luoyi Wu. Syntheses and characterization of γ-Fe2O3 nanowire arrays via a versatile, simple and low-cost method, Journal of Experimental Nanoscience 2012, 7(4): 477–484[8] Lei Yang, Yajuan She, Shihua Zhao, Shihai Yue, Qian Wang, Aiping Hu,Wei Zhang. Synthesis and optical properties modulation of ZnO/Eu2O3 nanocable Arrays, Journal of Applied Physics, 2010, 108 (10): 104301(1–6)[9] Lei Yang, Yuanhong Tang, Shihua Zhao. Synthesis and photoluminescence of ZnS macrolattice, Journal of Sol-Gel Science and Technology, 2010, 53 (2):154–161[10] Lei Yang, Yuanhong Tang, Zao Yang, Qian Wang. Synthesis of Eu2O3 nanowire arrays through a facile sol–gel template approach, Journal of Sol-Gel Science and Technology, 2008, 45 (1): 23–26[11] Lei Yang, Yuanhong Tang, Aiping Hu, Xiaohua Chen, Kui Liang, Lide Zhang. Raman scattering and luminescence study on arrays of ZnO doped with Tb3+ , Physica B, 2008, 403 (13-16): 2230–2234[12] Lei Yang, Yuanhong Tang, Xiaohua Chen, Yan Li, Xueli Cao. Synthesis of Eu3+ doped Y2O3 nanotube arrays throughan electric field-assisted deposition method, Materials Chemistry and Physics, 2007, 101 (1): 195–198[13] Lei Yang, Guozhong Wang, Chunjuan Tang, Hongqiang Wang, Lide Zhang. Synthesis and Phtoluminescence of corn like ZnO nanostructure under solvothermal-assisted heat treatment, Chemical Physics Letters, 2005, 409 (4-6): 337–341[14] Lei Yang, Yan Li, Yanhe Xiao, Changhui Ye, Lide Zhang. Synthesis of Tb3+-doped ZnO Nanowire Arrays Through a facile Sol-Gel Template Approach, Chemistry Letters, 2005, 34 (6): 828–829非第一作者论文[1] Shihua Zhao, Fangjie Shu, Yanmin Li, Cuimei Liu, Wenwen Shan, Yuting Cui, and Lei Yang. Synthesis and Luminescence Properties of ZnO:Eu3+ Nano crystalline via a facile solution method. Journal of Nanoscience and Nanotechnology, 2012, 12(3): 2607–2611[2] Shihua Zhao, Lingling Wang, Lei Yang, Zhiyong Wang. Synthesis and luminescence properties of ZnO:Tb3+ nanotube arrays via electrodeposited method, Physica B, 2010, 405 (15): 3200–3204[3] Shihua Zhao, Lei Yang, Lingling Wang, Benhai Yu, Yuxi Chen, Yuting Cui. Synthesis and Luminescence properties of ZnO:Eu3+ nanowire arrays via electrodeposited method, Functional Materials Letters, 2010, 3 (4): 285–288[4] Shihua Zhao, Huanfeng Ma, Lingling Wang, Lei Yang, Yuting Cui. Synthesis and luminescence properties of ZnO nanoneedle arrays via electrodeposited method. Surface Review and Letters, 2010, 17(4): 425–430[5] Shihua Zhao, Lingling Wang, Lei Yang, Yuxi Chen. Synthesis and ultraviolet luminescence properties of half-wall Al2O3 nanotube arrays, Journal of Physics D: Applied Physics 2009, 42 (22):225106 (1–7)[6] Luoyi Wu, Zhong Yang, Weijun Xia, Zhenhua Chen, Lei Yang, The cyclic softening and evolution of microstructures for Mg–10Gd–2.0Y–0.46Zr alloy under low cycle fatigue at 573 K, Materials and Design 36 (2012) 47–53[7] Zao Yang, Quan-Hui Liu, Lei Yang. The effects of addition of citric acid on the morphologies of ZnO nanorods, Materials Research Bulletin, 2007, 42 (2): 221–227[8] Yan Li, Changhui Ye, Lei Yang, Cheng Wang, C. R. Zheng, Lide Zhang. Synthesis and Growth of the Facet-tipped In2O3 Nanowires, Chemistry Letters, 2007, 36 (3): 442–443[9] Yan Li, Changhui Ye, Xiaosheng Fang, Lei yang, Yanhe Xiao, Lide Zhang. Fabrication and Photoluminescence of SiO2-Sheathed Semiconducting Nanowires: The Case of ZnS/SiO2, Nanotechnology, 2005, 16 (4): 501–505[10] Guosheng Wu, Ting Xie, Xiaoyou Yuan, Yan Li, Lei Yang, Yanhe Xiao, Lide Zhang. Controlled Synthesis of ZnO nanowires or nanotubes via sol-gel Temlate process, Solid State Communications, 2005, 134 (7): 485–489 |