个人资料
教育经历2004.09-2009.03 同济大学&法国里昂大学,理学博士(中法联合培养) 2000.09-2004.07 郑州大学,理学学士 工作经历2015.08-2016.08 法国巴黎综合理工大学 访问学者 2012.06-至今 华东师范大学 讲师、副教授 2009.08-2012.06 中国科学院上海硅酸盐研究所 博士后、助理研究员 个人简介读万卷书感古今之通变,行万里路知天地之广阔。勤于学,善于思,敏于行。
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社会兼职中国晶体学会陶瓷专业委员会、中国真空学会
研究方向研究生报考方向:无机光电材料 主要研究方向为:光电转换与功能薄膜材料及器件(Photoelectric Conversion and Functional Film Materials and Devices)。主要从事新型光电转换材料及功能薄膜材料的可控制备、物性研究以及应用开发等工作;具体方向包括:自组装仿生纳米材料(Self-assembly and Biomimetic Nanomaterials),光调控材料(Light Control Materials),能量转换/存储材料与器件(Energy Conversion/Storage Materials and Devices)。 1、仿生减反射光学薄膜 2、石墨烯薄膜 3、金属纳米线、石墨烯透明导电薄膜 招生与培养开授课程主讲课程: 本科生:《无机化学》、《无机及分析化学》、《无机化学实验》 研究生:《无机化学表征方法》、《材料前沿与生活》 科研项目主持(第一负责人): 国家自然科学基金青年科学基金项目(1项) 国家重点实验室开放基金项目(1项) 上海市重点实验室开放基金项目(2项) 上海高校本科重点教学改革项目(1项) 上海教委本科重点课程建设项目(1项) 学术成果论文发表: ❖W. Y. Yin, Y. Huang, M. Lu, Y. X. Tang, G. H. Zhang, D. Z. Li*. Controllable direct growth and patterning of graphene based transparent and conductive films on insulating substrates via Cu nanoparticles assisted-catalysis method. Diamond and Related Materials 2022, 123, 108868. ❖W. Du, G. H. Zhang, P. Chen, P. Y. Tang, J. Wang, D. Z. Li, J. S. Hou*, Y. Z. Fang*. Visible-light photoelectric response in semiconducting quaternary oxysulfide FeOCuS with anti-PbO-type structure. Chem. Commun.2021, 57, 13393–13396. ❖Y. X. Tang, W. Y. Yin, Y. Huang, G. H. Zhang, Q. B. Zhao, D. Z. Li*. All solution-processed silver nanowires composite silica nanospheres antireflection structure with synergetic optoelectronic performance. New Journal of Chemistry 2021, 45, 15215–15222. (Cover Paper) ❖G. H. Zhang*, J. S. Hou, M. J. Zhu, G. Q. Huang, D. Z. Li, Y. Z. Fang*, T. Zeng*. Visible-light Photovoltaic effect in High-Temperature Ferroelectric BaFe4O7. Journal of Materials Chemistry C 2020, 8, 16234. ❖Q. Lu, H. Guo, D. Z. Li*, Q. B. Zhao*. Determination of capsaicinoids by magnetic solid phase extraction coupled with UPLC-MS/MS for screening of gutter oil. Journal of Chromatography B 2020, 1158, 122344. ❖Q. Lu, H. Guo, Y. Y. Zhang, X. D. Tang, W. B. Lei, R. J. Qi, J. H. Chu, D. Z. Li*, Q. B. Zhao*. Graphene oxide-Fe3O4 nanocomposite magnetic solid phase extraction followed by UHPLC-MS/MS for highly sensitive determination of eight psychoactive drugs in urine samples. Talanta 2020, 206, 120212. ❖Q. Lu, L. Y. Liu, X. L. Zhang, Y. Cheng, Y. Huang, Y. K. Shan, Q. B. Zhao, G. H. Zhang, D. Z. Li*. Graphene transparent conductive films directly grown on quartz substrates by assisted catalysis of Cu nanoparticles. Journal of Materials Science 2019, 54(14), 10312–10324. ❖Y. Huang, J. Y. Lin, L. Y. Liu, Q. Lu, X. L. Zhang, G. H. Zhang, D. Z. Li*. Enhanced Performance of Graphene Transparent Conductive Films by Introducing SiO2 Bilayer Antireflection Nanostructure. New Journal Chemistry 2019, 43(48), 19063–19068. ❖Y. Cheng, H. Bi*, X. L. Che, D. Z. Li*, W. L. Ji, F. Q. Huang*. Suppression of graphene nucleation by plasma treatment of Cu foil for the rapid growth of large-size single-crystal graphene. Carbon 2019, 147, 51–57. ❖Y. Cheng, H. Bi*, X. L. Che, W. Zhao, D. Z.Li*, F. Q. Huang*. Rapid growth of large-area single-crystal graphene film by seamless stitching using resolidified copper foil on a molybdenum substrate. Journal of Materials Chemistry A 2019, 7(31), 18373–18379. ❖X. L. Zhang, Q. Lu, Y. Cheng, L. Y. Liu, Y. K. Shan, G. H. Zhang, D. Z. Li*. Moth-eye-like antireflection coatings based on close-packed solid/hollow silica nanospheres. Journal of Sol-Gel Science and Technology 2019, 90(2), 330–338. ❖G. Q. Huang, G. H. Zhang*, Z. P. Gao, J. W. Cao, D. Z. Li, H. Yun*, T. Zeng*. Enhanced visible-light-driven photocatalytic activity of BiFeO3 via electric-field control of spontaneous polarization. Journal of Alloys and Compounds 2019, 783, 943–951. ❖G. H. Zhang, J. W. Cao, G. Q. Huang, J. Li, D. Z. Li, W. F. Yao*, T. Zeng*. Facile fabrication of well-polarized Bi2WO6 nanosheets with enhanced visible-light photocatalytic activity. Catalysis Science & Technology 2018, 8, 6420–6428. ❖L. Y. Liu, Y. Cheng, X. L. Zhang, Y. K. Shan, X. Zhang, W. Y. Wang, D. Z. Li*. Graphene-based transparent conductive films with enhanced transmittance and conductivity by introducing antireflection nanostructure. Surface & Coatings Technology 2017, 325, 611-616. ❖S. S. Han, L. Y. Liu, Y. K. Shan, F. Yang, D. Z. Li*. Research of Graphene/Antireflection Nanostructure Composite Transparent Conducting Films. Journal of Inorganic Materials 2017, 32(2), 197–202. ❖S. S. Han, F. Yang, L. Y. Liu, M. Zhou, Y. K. Shan, D. Z. Li*. Direct Growth of Graphene on Different Templates to Fabricate Special Shapes of Graphene by Remote Catalyzation of Cu Nanoparticles. Journal of Materials Science & Technology 2017, 33(8), 800-806. ❖S. S. Han, D. Z. Li*,Y. K. Shan*, K. Yuan. Research of Antireflection and Visible Luminescence Performance of SiO2 film doped with Eu3+. Jouranl of Rare Earth & Application 2015, 1, 1–6. ❖D. Z. Li, S. S. Han, A. M. Li, Y. M. Wang, Y. K. Shan*, F. Q. Huang*. Novel-Type Nanostructured SiO2 Antireflection Coatings and Their Application in Cu(In,Ga)Se2 Solar Cells. Materials Chemistry and Physics 2015, 165, 97–102. ❖李德增*,陈波. 自主探究、分层式实验教学改革探索. 第13届全国大学化学教学研讨会 2015. P305–308. (会议论文) ❖李德增*,陈波. 突破衍射极限--探索纳米世界的超分辨显微技术. 化学教学 2015, 37(1), 12–15,19. (邀请文章) ❖D. Z. Li, Z. Q. Liu, Y. M. Wang*, Y. K. Shan, F. Q. Huang*. Efficiency Enhancement of Cu(In,Ga)Se2 Solar Cells by Applying SiO2–PEG/PVP Antireflection Coatings. Journal of Materials Science & Technology 2015, 31(2), 229–234. ❖D. Z. Li,Y. K. Shan*, F. Q. Huang*, S. J. Ding. Sol–Gel Preparation and Characterization of SiO2 coated VO2 Films with Enhanced Transmittance and High Thermochromic Performance. Applied Surface Science 2014, 317, 160–166. ❖D. Z. Li, D. Y. Wan, X. L. Zhu, Y. M. Wang*, Z. Han, S. S. Han, Y. K. Shan*, F. Q. Huang*. Broadband Antireflection TiO2–SiO2 Stack Coatings with Refractive-Index-Grade Structure and Their Applications to Cu(In,Ga)Se2 Solar Cells. Solar Energy Materials & Solar Cells 2014, 130(11), 505–512. ❖D. Z. Li, Y. K. Shan*. Function Synergistic Effect of Broadband Antireflection and Thermochromism on SiO2 coated VO2 films. Proceeding of International Conference on Emerging Information, Technology & Materials 2013. ❖S. J. Ding, Z. Q. Liu, D. Z. Li, W. Zhao, Y. M. Wang, D. Y. Wan, F. Q. Huang*. Tunable Assembly of Vanadium Dioxide Nanoparticles to Create Porous Film for Energy-Saving Applications. ACS Applied Materials & Interfaces 2013, 5(5), 1630–1635. ❖D. Z. Li, G. M. Wu*, G. H. Gao, J. Shen, F. Q. Huang*. Ultrafast Coloring-Bleaching Performance of Nanoporous WO3–SiO2 Gasochromic Films Doped with Pd Catalyst. ACS Applied Materials & Interfaces 2011, 3(12), 4573–4579. ❖D. Z. Li, F. Q. Huang*, S. J. Ding. Sol–gel Preparation and Characterization of Nanoporous ZnO/SiO2 Coatings with Broadband Antireflection Properties. Applied Surface Science 2011, 257(23), 9752–9756. ❖Y. W. Huang, D. Z. Li, J. H. Feng. G. F. Li, Q. Zhang*. Transparent Conductive Tungsten-Doped Tin Oxide Thin Films Synthesized by Sol–Gel Technique on Quartz Glass Substrates. Journal of Sol−Gel Science Technology 2010, 54(3), 276–281. ❖D. D. Lekeufack, A. Brioude*, A. W. Coleman, P. Miele, J. Bellessa, D. Z. Li, P. Stadelmann. Core-Shell Gold J-Aggregate Nanoparticles for Highly Efficient Strong Coupling Applications. Applied Physics Letters 2010, 96(25), 253107(1−3). ❖D. Z. Li, C. Symonds*, F. Bessueille, J. C. Plenet, A. Errachid, G. M. Wu, J. Shen, J. Bellessa. Transfer of Optically Active Polyelectrolyte Multilayers by Micro-Contact Printing. Journal of Optics A: Pure and Applied Optics 2009, 11(6), 065601(1−5). 学术评价: 入选2019年《无机材料学报》材料领域各方向优秀论文Top 10 “石墨烯/纳米减反结构:高效透明导电薄膜。石墨烯具有超高的载流子迁移率、高的光学透过率、优良的热力学特性、优异的柔韧性。其作为透明电极虽有巨大潜力,但却需要深度改进。华东师范大学李德增研究团队,在纳米氧化硅球阵列减反结构基底上, 生长了连续的、低缺陷的、层数可控的石墨烯,成为性能优异的复合透明导电薄膜, 有望用于光伏、导电等诸多领域,极大地扩大了应用范围。” 专利申请: 申请专利共12个,其中已授权9个; ZL201810462847.X 紧密排布的复合二氧化硅纳米球阵列结构及仿蛾眼减反结构和制备方法
荣誉及奖励❖上海师范院校教师智慧教学大赛二等奖; ❖2019年华东师范大学本科教学成果一等奖; ❖首届长三角师范院校教师智慧教学大赛三等奖; ❖华东师范大学2019年度本科教学年度贡献奖; ❖华东师范大学第十二届青年教师教学比赛二等奖等; ❖《无机材料学报》2019年度优秀论文; ❖全国博士学术论坛(物理学)(Doctoral Forum of China in Physics)优秀宣读论文; |