方应翠

2018-10-23
姓 名方应翠

职 称教授
职 务
所属系真空与过程装备工程系
邮 箱ycfang@hfut.edu.cn
电 话18155169469
个人基本情况

方应翠,太阳集团tyc5997教授,博士生导师,中国真空学会薄膜专委会委员,安徽省真空学会副理事长。19907月毕业于太阳集团tyc5997真空技术及设备专业,19907月至19957月在芜湖市电子管厂任工艺员,19958月至19987月在中国科学院等离子体物理研究所攻读硕士。自19987月至今,在太阳集团tyc5997真空教研室任助教、讲师、副教授和教授。期间20028月至20056月在复旦大学材料科学系物理电子学专业攻读博士学位,200510月到200810月在中国科技大学微尺度国家实验室做博士后,20112月到20122月在美国佐治亚理工学院做访问,20168-9月在瑞典皇家理工学院应用物理系交流访问,20198-9月在美国匹兹堡大学航空与应用物理系交流访问。获中国科学院等离子体物理所所长奖,获复旦大学研究生创新基金,中国博士后基金,安徽省自然科学基金,国家自然科学基金资助。发表各类学术和会议论文近百篇,获批国家授权发明专利6项。分别荣获太阳集团tyc59972002-20032013-2014年度三育人奖。培养的研究生多人次获国家奖学金,中国真空学会硕士研究生奖学金以及各种学术会议奖项。

主要研究方向
1. 薄膜和纳米颗粒的真空制备、表征和性能研究
2. 低能激光、等离子体与表面相互作用
3. 表面等离激元共振增强/阻尼特性
开设课程

《真空镀膜技术与设备》

《真空系统设计与计算》

《专业英语》

《纳米技术》

《表面分析》

《纳米薄膜光子学》

近年的科研项目、专著与论文、专利、获奖

科研项目

1. 国家自然科学基金-区域创新发展联合重点基金,“共蒸发制备铜锑硒薄膜及其柔性太阳电池研究”,2020-2023,参与

2. 国家自然科学基金面上项目,表面等离激元强衰减体系中热载流子产生、输运及光催化机制的研究, 2017-2020,项目负责人。

3. 安徽省自然科学基金面上项目“表面等离激元共振强阻尼体系的构建和光催化特性的研究”2017-2019,项目负责人
4. 合作项目,聚变装置第一镜制备和表征,2015-2016,项目负责人。
5. 合作项目,EAST多功能内部线圈导体接头真空检漏技术开发,2013-2015,项目负责人。
6. 国家自然基金主任基金,等离子体尾场及光与物质的相互作用,2012-2014,参与。

学术论文:

1.     Yingcui Fang*, Zhitao Cheng, Shuai Wang, Hongliang Hao, Lei Li, Shiqi Zhao, Xiangqian Chu, Rensheng Zhu, Effects of oxidation on the localized surface plasmon resonance of Cu nanoparticles fabricated via vacuum coating, Vacuum 184, 109965, 2021. https://doi.org/10.1016/j.vacuum.2020.109965

2.     H. Hao, H.H. Li, S. Wang, Z. Cheng, Y. Fang*, Epitaxial growth of AgCu bimetallic nanoparticles via thermal evaporation deposition, Appl. Surf. Sci.505,143871,2020.  https://doi.org/10.1016/j.apsusc.2019.143871

3.     Huanhuan Li, Mengting Si, Lihua Liu, Xiangqian Chu, Shuai Wang, Lei Wan, Rong Yan,Mengtao Sun, and Yingcui Fang*, Ag Nanoparticle-Induced Oxidative Dimerization of Thiophenols: Efficiency and Mechanism, Langmiur 34(38) 11347-11353, 2018

4.     Huanhuan Li , Qingmeng Wu, Lihua Liu, Bing Zhang, Mengting Si, Zhong Li, Qi Jin, Yiqing Chen, Jie Shen, Yingcui Fang*, Effect of Configuration on the Photocatalytic Activity of AgNPs-TiO2 System, Plasmonics13:2345-2351, 2018

5.     Yingcui Fang*, Qingmeng Wu, Huanhuan Li, Bing Zhang, Rong Yan, Junling Chen, and Mengtao Sun, Photocatalytic activity of silver oxide capped Ag nanoparticles constructed by air plasma irradiation, Appl. Phys. Lett. 112, 163101, 2018.

6.     Qingmen Wu , Mengting Si, Bing Zhang, Kang Zhang, Huanhuan Li, LongfeiMi, Yang Jiang , YanRong, Junling Chen ,Yingcui Fang*, Nanotechnology, 29, 295702, 2018.

7.     Yingcui Fang*, Bing Zhang, Kang Zhang, Gongpu Li, Jun Jiang, Rong Yan and Junling Chen, Mechanism of photocatalytic activity improvement of AgNPs/TiO2 by oxygen plasma irradiation, Nanoscale, 2016, 38, 17004-17011.

8.     Yingcui Fang*, Jinjun He, Kang Zhang, Chuanyun Xiao, Bing Zhang, Jie Shen, Haihong Niu, Rong Yan and Junling Chen, Ar plasma irradiation improved optical and electrical properties of TiO2/Ag/ TiO2 multilayer thin film. Optic. Lett., 2015,40, 5455-5458.

9.     Fang Yingcui*, Zhang B, Hong L, Yao D, Xie Z and Jiang Y, Improvement of photocatalytic activity of silver nanoparticles by radio frequency oxygen plasma irradiation. Nanotechnology, 2015, 26, 295204.

10.  Yingcui Fang,Yang Zhang, Hongying Gao,Liuguo Chen, Bo Gao, Weizhen He, QiushiMeng, Chao Zhang, Zhenchao Dong, Modulation of porphyrin photoluminescence by nanoscale spacers on silicon substrates, Appl.Surf. Sci., 2013, 285, 572-576.

11.  Ying-cui Fang*,Liu Hong, Kuan-xiang Zhang, Xin Lu, Chun-mei Wang, Jun Yang, XiaoliangXu, Localized surface plasmon of Ag nanoparticles affected by annealing and its coupling with the excitons of Rhodamine 6G, J. Vac. Sci. Tech. A., 2013, 31, 041401.

12.  Ying-cui Fang*, Kevin Blinn, Xiaxi Li, Guojun Weng, and Meilin Liu, Strong coupling between Rhodamine 6G and localized surface plasmon resonance of immobile Ag nanoclusters fabricated bydirect currentsputtering. Appl. Phys. Lett., 2013, 102, 143112.

13.  Ying-cui Fang*, X. X. Li, K. Blinn, A. M. Mahmoud, and M. L. Liu, Resonant surface Enhancement of Raman scattering of Ag nanoparticles on silicon substrates fabricated by dcSputtering. J. Vac. Sci. Tech. A, 2012, 30, 050606.

14.  Xiaxi Li, Kevin Blinn, Ying-cui Fang, Mingfei Liu, Mahmoud A. Mahmoud, Shuang Cheng, Lawrence A. Bottomley, Mostafa El-Sayed and Meilin Liu, Applicationof surface enhanced Raman spectroscopy to the study of SOFC electrode surfaces.Phys. Chem. Chem. Phys., 2012, 14, 5919-5923.

15.  Zhang Kuan-Xiang, Wang wen, Zhao Jian-Hua, Hou Ji-Lai, Zhang Yan and Ying-cui Fang*, Hydrophilicity Difference of TiO2 Thin Films Induced by Different Plasmas. Physics Procedia, 2012, 32, 356-362.

16.  Kuan-Xiang Zhang, Wen Wang, Ji-Lai Hou, Jian-Hua Zhao, Yan Zhang, Ying-Cui Fang*Oxygen Plasma Induced Hydrophilicity of TiO2 Thin Films, Vacuum, 2011, 85, 990-993.

17.  Y.C.Fang*, Z.J.Zhang and M.Lu, Room Temperature Photoluminescence Mechanism of SiOx Film after Annealing at Different Temperatures, J. of Lumi., 2007, 26, 145.

18.  Y.C.Fang*, Z.J.Zhang, J. Shen and M.Lu, Photoluminescence from Electron-Beam Deposited CeO2 Thin Film after High Temperature Thermal Annealing, Chin. Phys. Lett., 2006, 23, 1919.

19.  Y.C.Fang, Z.J.Zhang, Z.Q.Xie and Y.Y.Zhao, Photoluminescence Enhancement of Si Nanocrystals Embedded in SiO2 Matrix by Doping CeF3. Appl. Phy. Lett., 2005, 86, 191919.

20.  Y.C.Fang, Z.J.Zhang, Z.Q.Xieand M. Lu, The effects of CeF3 doping on thephotoluminescence of Si nanocrystals embedded in a SiO2 matrix, Nanotechnology, 2005, 16, 769.

21.  Y.C.Fang, Z.J.Zhang, Z.Q.Xie and Y.Y.Zhao, Photoluminescence from SiOx thin films: effects of film thickness and annealing temperature. Nanotechnology , 2004, 15, 494-500.

22.  Y.C.Fang, W.Q. Li, L.J.Qi, L.Y.Li, Y.Y.Zhao, Z.J.Zhang and M.Lu, Photoluminescence of SiOx thin films after annealing at various temperatures, Chin. Phys. Lett., 2003, 11, 2042.

23.  Y.C.Fang, W.Q. Li, L.J.Qi, Z.J.Zhang and M.Lu, Peak position of photoluminescence of Si Nanocrystals versus thickness of SiOx thin films, Chin. Phys. Lett., 2003, 12, 2252. 

主编教材:
《真空镀膜原理与技术》,科学出版社,2014.2出版。

授权发明专利:

1. 一种快速检测果皮中残留啶虫脒的方法(ZL 201610513632.7

2. 一种增强纳米银/二氧化钛光催化性能的方法(ZL 201510073794.9

3. 一种提高介质/金属/介质光学性能的方法(ZL 2015 1 0164428.4

4. 一种对硅量子点掺杂的方法(ZL 200410025433.9

5. 一种提高纳米银膜导电性的方法(ZL 2015 1 0121535.9

6. 一种增强纳米银薄膜光催化特性的方法(ZL 2014 1 0188692.7  



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