文建湘 博士，教授

办公室：
上海大学宝山校区东区通信实验12楼B417办公室

通信地址(邮政编码):
上海市宝山区上大路99号上海大学通信学院（200444）

电话：


电子邮件：
wenjx@shu.edu.cn

个人主页：
https://scie.shu.edu.cn/Prof/wenjx.htm


个人简历：
文建湘，工学博士，教授，博士生导师。2011年获上海大学与澳大利亚新南威尔士大学联合培养博士学位。目前在上海市特种光纤与光接入网省部共建教育部重点实验室（国家实验室培育基地）从事特种光纤设计与制造、光纤通信、光纤激光器与光纤传感等应用研究。目前担任上海市先进光波导智能制造与测试专业技术服务平台副主任；上海市惯性技术学会副秘书长；2020 ACP会议TPC成员。
2009-2010年国家公派澳大利亚新南威尔士大学从事学术交流，并与澳大利亚新南威尔士大学光子通信实验中心建立长期合作关系，负责组织主办四届（2015，2016，2017，2019）中国－澳大利亚•特种光纤国际研讨会；国际合作交流紧密，多次受邀参加国际重要会议OFS/CLEO/ACP/APOS等，最近几年多次与悉尼大学、丹麦科技大学，丹麦科学院、法国里尔-1科技大学、美国麻省理工学院（MIT）与瑞士洛桑联邦理工（EPFL）等进行学术交流。发表研究论文六十多篇，其中SCI、EI收录五十余篇，授权发明专利近十余项，受邀参与撰写三本英文书籍多章节(Bismuth,ISBN 978-953-51-6012-0)，并担任英文书籍Bismuth-Fundamentals and Photonic Applications(ISBN: 978-1-83968-243-8) 联合主编。
2016-2019年间多次获上海市－南京市－哈尔滨市惯性技术与导航学术研讨会 “优秀论文”奖；2015年获 “优秀班导师”称号；2010年获澳大利亚新南威尔士大学Photonics Research Scholarship(1st Class)；2009年获国家公派专项研究生奖；2001-2007年在江苏法尔胜光子公司从事光纤的研发与技术管理，参与国家“十五”科技攻关计划“光纤预制捧产业化技术开发”，国家863“保偏光纤”项目，其产品主要应用于神舟六号、七号飞船；2008年获江苏省科学技术进步奖二等奖；精通MCVD、ALD工艺对新型特种光纤的研制与开发，在特种光纤的设计与制备方面积累大量的实践经验。
主要学术与工作经历
2018/3–至今， 上海大学，通信与信息工程学院，教授
2013/3–2018/2，上海大学，通信与信息工程学院，副教授
2011/6–2013/3，上海大学，通信与信息工程学院，讲师
2007/9-2011/3，上海大学与澳大利亚新南威尔士大学联合培养　博士
2001/7-2007/9，江苏法尔胜光子有限公司，光纤制造主管/研发工程师

科研方向：
1) 新型掺杂有源光纤与涡旋光束传输光纤及涡旋增益放大光纤结构设计与制备。如Bi3+/ Er3+/Al3+/Yb3+掺杂系列石英光纤，高增益晶体光纤，包括C波段、L波段与C+L波段应用于高增益超宽谱光放大、光纤激光与超宽谱光源；涡旋光放大与高阶光纤激光器；窄线宽、单频与可调谐光纤激光器；激光医疗、生物医疗，以及少模增益光放大等。
2) 特种光纤辐射特性研究，利用新工艺技术开发抗辐射光纤与光器件，如抗辐射单模、少模与多模石英光纤，抗辐射偏振保持光纤及抗辐射有源特种光纤等。主要应用于航空、航天、军事领域系统的通信及传感器件，如空间飞行器导航与姿态控制的光纤陀螺仪，核潜艇水听器；核爆炸诊断技术、核反应堆放射源内部监测，复杂环境下军事通信与物联网技术应用，以及光纤传感与光器件的防辐射和防腐蚀特性等。
3) 具有新颖光学特性石英光纤的结构设计与开发。主要应用于高能物理、核物理、核医学成像、工业探测等闪烁光纤，如Ce3+掺杂石英光纤；半导体掺杂有源光纤，如Bi2O3、PbS、PbO掺杂光纤；高压电流光纤传感的高磁光效应低双折射光纤，如Pb(2+), Bi(m+), Tb3+掺杂光纤，可见光波段与紫外波长的光源与激光器，以及应用于随机激光掺杂光纤的结构设计与制备等。
本科生教学
本科课程： 光电信息技术、信息工程与社会科学、光电材料；　
研究生课程：通信与信息技术进展，光波导理论；　
每年招收毕业设计3-4名、优秀本科生2-3名；

研究生培养：
已毕业学生：2011王朴朴(中国电子科技集团第23研究所)；2012王洁(国家电网安徽电力)；2013刘文君(光华一等奖学金) (上海联通)；2014王杰（上海浦东发展银行），王文娜（上海量投网络科技）；2015郭琪（百度，上海），詹海虹（小红书，上海）；2016邢建飞(携程，上海)，陈丽君（上海联通），刘正（锐科光电）；2017贺心雨(中天科技)，车倩倩(上海钧正网络科技)，蔡奇招（广州网易）。指导博士研究生1名（上海大学）；
在读研究生：叶乐，陈子睿，曾嘉伟，邹凯，杨磊，李田田，黄家祺
在读博士生：万英，吴研
拟招生学生情况：
欢迎具有光通信与光传感、光纤通信技术、光子学与光学以及通信专业背景的学生报考研究生与博士研究生。
同时，欢迎具有光通信与光传感、光纤通信技术，以及光纤激光器背景的优秀博士从事博士后研究，详情请邮件联系：E-mail: wenjx@shu.edu.cn。

承担或参与的科研项目：
1) 2019年获华为技术有限公司技术开发重点项目：XXX光纤研究，2019/11- 2020/12，（主持, 在研）
2) 2019年获国家自然科学基金面上项目：宽谱增益涡旋光纤及放大特性研究；(项目号：**) (主持,　在研）
3) 2019年获国家自然科学基金重点项目：深空光纤陀螺用耐辐照、低损耗空芯光子带隙保偏光纤及器件研究；(项目号：**) (参与单位主持,在研）
4) 2019年获“十三五”全军共用信息系统装备预先研究项目：***有源光纤***；(参与单位主持,在研）
5) 2018获深圳太辰光通信有限公司：磁光光纤特性研究；（主持，结题）
6) 2017获江苏法尔胜光电科技公司：有源光纤特性研究；（主持，结题）
7) 2017年获军委科技委装备发展部预研项目：***光纤特性研究；（项目号：****40302）（主持,在研）
8) 2015年获国家自然科学基金重点国际合作研究项目：超宽谱铋铒镱共掺石英光纤研究；(项目号：) (负责人,在研）
9) 2015年获上海市科委国际合作项目：基于未来物联网超高速、超大容量光通信应用铋/铒共掺放大光纤研究；(主持,结题）
10) 2012年获国家自然科学基金面上项目：超宽带、高增益掺铋石英光纤及其光放大特性研究； (主持,结题）
11) 2012年获上海市自然科学基金项目：铋铝共掺超宽带石英光纤的研究； (主持,结题）

学术论文及授权发明专利：
学术论文：
1) Ying Wan, Jianxiang Wen*, Yanhua Dong, Chen Jiang, Ming Jia, Fengzai Tang, Na Chen, Ziwen Zhao, Sujuan Huang, Fufei Pang, And Tingyun Wang, Exceeding 50% slope efficiency DBR fiber laser based on a Yb-doped crystal-derived silica fiber with high gain per unit length, Optics Express, 28, 16, 23771-23783(2020).
2) MingJia, JianxiangWen*, WenyunLuo, YanhuaDong, FufeiPang, ZhenyiChen, GangdingPeng, TingyunWang, Improved scintillating properties in Ce:YAG derived silica fiber with the reduction from Ce4+ to Ce3+ ions, Journal of Luminescence, 221, 117063, 1-7 (2020).
3) Jianxiang Wen*, Qianqian Che, Yanhua Dong, Qi Guo, Fufei Pang, Zhenyi Chen, and Tingyun Wang, Irradiation effect on the magneto-optical properties of Bi-doped silica optical fiber based on valence state change, Optical Materials Express, 10,1(1), 88-98 (2020).
4) Ziming Guo, Huanhuan Liu , Lina Xiang, Lifei Chen, Junfeng Yang, Jianxiang Wen ,Yana Shang, Tingyun Wang , and Fufei Pang, Generation of Perfect Vortex Beams With Polymer-Based Phase Plate, IEEE Photonics Technology Letters, 32, 10,565-568 (2020).
5) Yanhua Dong, Caiyun Su, Xiangping Pan, Yangyang Zhao, Jianxiang Wen, Fufei Pang, Yi Huang,Yana Shang, Tingyun Wang, Density functional theory investigation on formation of nanoscale PbS materials and its fabrication in silica optical fiber via atomic layer deposition, Optical Fiber Technology, 58, 102257(2020).
6) Yeming Zhang, Yue Sun, Jianxiang Wen, Shichao lu, Xusheng Xiao, Zhijun Ma, Luyun Yang, Gang Bi, Haitao Guo, Jianrong Qiu, Investigation on the formation and regulation of yttrium aluminosilicate fiber driven by spontaneous element migration, Ceramics International, 45, 19182-19188 (2019).
7) Teng Wang, Ao Yang, Fan Shi, Yiping Huang, Jianxiang Wen, and Xianglong Zeng , High-order mode lasing in all-FMF laser cavities, Photonics Research, 7, 1, 42-48(2019).
8) Jiajia Zheng, Yanhua Dong, Xiangping Pan, Jianxiang Wen, Zhenyi Chen, Fufei Pang, Yana Shang, Yanhua Luo, Gang-ding Peng, and Tingyun Wang. Ultra-wideband and flat-gain optical properties of the PbS quantum dots-doped silica fiber. Optics Express, 27(26): 37900-37909 (2019).
9) Qiancheng Zhao, Jiquan Zhang, Dan Sporea, Yanhua Luo, Jianxiang Wen, Gangding Peng, Gamma radiation and thermal-induced effects on the spectral performance of BACs in Bi/Er codoped aluminosilicate fibers, Optics Express, 27(7): 9955-9964(2019).
10) Xiangping Pan,Yanhua Dong, Jiajia Zheng, Jianxiang Wen, Fufei Pang, Zhenyi Chen, Yana Shang, Tingyun Wang, Enhanced FBG Temperature Sensitivity in PbS-Doped Silica Optical Fiber, Journal of Lightwave Technology, 37,18, 4902 – 4907 (2019)
11) Mingjie Ding, Desheng Fan, Justin B Davies, Bowen Zhang, Binbin Yan, Xinghu Fu, Gangding Peng, Yanhua Luo, Jianxiang Wen, Jiajun Ma, Spectroscopic study of the radiation hardening of bismuth/erbium co-doped optical fiber (BEDF) by hydrogen loading, Optical Materials,95, 109246-109251(2019).
12) Mingjie Ding, Bowen Zhang, Jie Fang, Yanhua Luo, Gang-Ding Peng, Jianxiang Wen, Jianzhong Zhang, and Binbin Yan, Spectroscopic properties of bismuth/erbium co-doped fiber at room temperature and liquid nitrogen temperature, Optical Materials Express, 9(9): 3604-3615(2019).
13) Gang-Ding Peng, Yanhua Luo, Jiangzhong Zhang, Jianxiang Wen,Yushi Chu, Kevin Cook, and John Canning，3D Silica Lithography for Future Optical Fiber　Fabrication，Handbook of Optical Fiber，Springer Reference Publish, 2019. (ISBN 978-981-10-7086-0)
14) Jianxiang Wen* , Xinyu He, Jianfei Xing, Junfeng Yang,Fufei Pang , Xianglong Zeng , Zhenyi Chen, and Tingyun Wang, All-Fiber OAM Amplifier With High Purity and Broadband Spectrum Gain Based on Fused Taper Vortex-Beam Coupler, IEEE Photonics Journal, 6(10),2018, **：1-9.
15) Jianfei Xing , Jianxiang Wen *, Jie Wang, Fufei Pang,Zhenyi Chen, Yunqi Liu, and Tingyun Wang，All-fiber linear polarization and orbital angular momentum modes amplifier based on few-mode erbium-doped fiber and long period fiber grating，Chinese Optics Letters，16（10）2018，100604-1-4.
16) Yanhua Luo, Binbin Yan, Jianxiang Wen, Jianzhong Zhang, and Gang-Ding Peng, Measurement of Optical Fiber Amplier. Handbook of Optical Fiber，Springer Reference Publish, 2018.
17) Shuen Wei, Mingjie Ding, Desheng Fan, Yanhua Luo, Jianxiang Wen and Gang-Ding Peng, Bismuth-Advanced Applications and Defects Characterization, ItechOpen Chapter 8, 2018
18) Jiangying Xia, Kang Xie, Jiajun Ma, Xianxian Chen, Yaxin Li, Jianxiang Wen, Jingjing Chen, Junxi Zhang, Sizhu Wu, Xusheng Cheng and Zhijia Hu* The transition from incoherent to coherent random laser in defect waveguide based on organic/ inorganic hybrid laser dye, Nanophotonics 2018; 7(7): 1341–1350
19) Binbin Yan, Yanhua Luo, Amirhassan Zareanborji, Gui Xiao, Gang-Ding Peng and Jianxiang Wen, Performance comparison of bismuth/erbium co-doped optical fibre by 830nm and 980nm pumping, J. Opt. 18 (2016): 105705-1-9.
20) Qiancheng Zhao, Jianzhong Zhang, Yanhua Luo, Jianxiang Wen, John Canning and Gang-Ding Peng, Energy transfer enhanced near-infrared spectral performance in bismuth/erbium codoped aluminosilicate fibers for broadband application, Vol. 26, Issue 14, Optics Express, 2018: 17889-17898.
21) Qi Guo, Jianxiang Wen,* Yi Huang, Wenna Wang, Fufei Pang, Zhenyi Chen, Yanhua Luo, Gang-Ding Peng, Tingyun Wang, Magneto-optical properties and measurement of the novel doping silica, optical fibers, Measurement 127 (2018) 63-67.
22) 文建湘*, 王文娜,王廷云等，伽马射线辐照对掺铅石英光纤的磁光特性影响，无机材料学报，33, 4, 2018: 416-420.
23) Ziwen Zhao, Xueli Cheng, Ting Hea, Fei Xue, Wei Zhang, Na Chen, Jianxiang Wen, Xianglong Zeng, Tingyun Wang，Effect of controlling recrystallization from the melt on the residual stress and structural properties of the Silica-clad Ge core fiber，Optical Fiber Technology，37，2017：6–10.
24) Tianyu Tu, Fufei Pang, Shan Zhu, Jiajing Cheng, Huanhuan Liu, Jianxiang Wen, And Tingyun Wang, Excitation of Bloch surface wave on tapered fiber coated with one-dimensional photonic crystal for refractive index sensing, Optics Express, 2017, 25, 8: 9019-9028.
25) Yanhua Luo, Binbin Yan, Qijin Zhang, Gang-Ding Peng, Jianxiang Wen and Jianzhong Zhang, Fabrication of Polymer Optical Fibre (POF) Gratings, Sensors, 2017, 17(3):511-531.
26) Wenjie Xu, Zhenyi Chen, Na Chen, Heng Zhang, Shupeng Liu, Xinmao Hu, Jianxiang Wen and Tingyun Wang, SERS Taper-Fiber Nanoprobe Modified by Gold Nanoparticles Wrapped with Ultrathin Alumina Film by Atomic Layer Deposition, Sensors, 2017, 17(3), 467-472.
27) Yunhe Zhao, Yunqi Liu, Chenyi Zhang, Liang Zhang, Guangjun Zheng, Chengbo Mou, Jianxiang Wen, and Tingyun Wang, All-fiber mode converter based on long-period fiber gratings written in few-mode fiber, Optics Letters, 2017, 42, 22: 4708-4711.
28) Yu Zhang, Fufei Pang, Huanhuan Liu, Sujuan Huang, Jianxiang Wen, Tingyun Wang, Generation of the First-Order OAM Modes in Ring Fibers by Exerting Pressure Technology, IEEE Photonics Journal, 2017, 9 (2),
29) Huangchao Chen, Jianxiang Wen, Yi Huang, Weilong Dong, Fufei Pang, Yanhua Luo, Gang-ding Peng, Zhenyi Chen, Tingyun Wang, Influence of linear birefringence on Faraday effect measurement for optical fibers, Optoelectronics Letters, 2017, 13,2: 147-150.
30) Zhijia Hu, Jiangying Xia, Yunyun Liang, Jianxiang Wen, Enming Miao, Jingjing Chen, Sizhu Wu, Xiaodong Qian, Haiming Jiang, and Kang Xie, Tunable random polymer fiber laser, Optics Express, 25, 15, 2017: 18421-18430.
31) Xinxin Sun, Jianxiang Wen*, Qiang Guo, Fufei Pang, and Tingyun Wang, Fluorescence properties and energy level structure of Ce-doped silica fiber materials, Optical Materials Express,7,3,2017:751-760.
32) Qiang Guo, Xinxin Sun, Wenyun Luo, Jianxiang Wen, Fufei Pang, Chengbo Mou, Gang-Ding Peng, And Tingyun Wang, Scintillation and photoluminescence property of SiO2 cladding YAP:Ce optical fiber via modified rod-in-tube method, Optical Materials Express,7,5,2017: 1525-1535
33) YanaShang, JianxiangWen*, YanhuaDong, HaihongZhan, YanhuaLuo, Gang-Ding Peng, XiaobeiZhang, FufeiPang, ZhenyiChen, TingyunWang, Luminescence properties of PbS quantum-dot-doped silica optical fibre produced via atomic layer deposition, Journal of Luminescence, 187, 201-204 (2017).
34) Fu Qin, Yanhua Dong, Jianxiang Wen, Fufei Pang, Yanhua Luo, Gang-ding Peng, Zhenyi Chen, and Tingyun Wang. Effect of heat treatment on absorption and fluorescence properties of PbS-doped silica optical fibre. Optical Materials, 64:468-473 (2017).
35) Jianxiang Wen*, Tingyun Wang, et al., Effects of Quenching, Irradiation, and Annealing Processes on the Radiation Hardness of Silica Fiber Cladding Materials (I), Optical Fiber Technology, 30.95-99 (2016).
36) Jianxiang Wen*, Yanhua Dong, et al., Radiation-induced photoluminescence enhancement of Bi/Al-codoped silica optical fibers via atomic layer deposition, Optics Express,23,22, 29004-29013(2015).
37) Jianxiang Wen*, Wenjun Liu, Yi Huang, Yuchen Liu, Yanhua Luo,Gang-Ding Peng, Fufei Pang, Zhenyi Chen,and Tingyun Wang, Spun related effects on optical properties of spun silica optical fibres, Journal of Lightwave Technology, 33, 12, 2674-2678 (2015).
38) Jianxiang Wen*, Wenjun Liu, Yanhua Dong, Yanhua Luo, Gang-ding Peng, Na Chen, Fufei Pang, Zhenyi Chen, and Tingyun Wang, Photoluminescence properties of Bi/Al-codoped silica optical fiber based on Atomic Layer Deposition method, Applied Surface Science, 347, 2015: 287-291
39) Yanhua Dong, Jianxiang Wen, Qing Guo, et al., Formation and Photoluminescence Property of PbS Quantum Dots in Silica Optical Fiber based on Atomic Layer Deposition, Optical Materials Express, 5, 4, 2015:712-719.
40) Yanhua Dong, Jianxiang Wen, Fufei Pang,et al., Optical properties of PbS-doped silica optical fiber materials based on atomic layer deposition, Applied Surface Science, 320, 2014: 372-378.
41) Jianxiang Wen*, Tingyun Wang, Fufei Pang, et al., Photoluminescence Characteristics of Bi(m+)-Doped Silica Optical Fiber: Structural Model and Theoretical Analysis, Jpn. Journal of Applied Physics, 52, 2013, 122501.
42) Jianxiang Wen, Jianchong Yin,et al., Mechanism of E' center induced by  ray radiation in silica optical fiber material. Nuclear Science and Techniques, 24 (2013) 040206: 1-4.
43) Yanhua Luo, Jianxiang Wen, Jianzhong Zhang, et al., Bismuth and Erbium co-doped optical fiber with ultra broadband luminescence across O-, E-, S-, C- and L-bands, Optics Letters, 37, 16 , 2012: 3447-3449.
44) Jianxiang Wen*, Gang-Ding Peng, et al., Gamma irradiation effect on Rayleigh scattering in low water peak single-mode optical fibers, Optics Express，19，23，2011：23271-23278.
45) Jianxiang Wen*, Wenyun Luo, Zhongyin Xiao,et al., Formation and conversion of defect centers in low water peak single mode optical fiber induced by gamma rays irradiation，Journal of Applied Physics, 107, 044904 (2010), 044904(1-5).
46) Tingyun Wang, Xianglong Zeng, Jianxiang Wen, et al., Characteristics of photoluminescence and Raman spectra of InP doped silica fiber, Applied Surface Science, 255, (2009) 7791–7793.
47) Wenyuan Wang, Jianxiang Wen, Fufei Pang,et al., All Single-Mode Fiber Fabry- Pérot Interferometric High Temperature Sensor Fabricated with Femtosecond Laser. Chinese Journal of Lasers, 2012, 39(10): **.
48) Tingyun. Wang, Jianxiang Wen*, Wenyun. Luo, et al., Influences of irradiation on network microstructure of low water peak optical fiber material, Journal of Non-Crystalline Solids 356 (2010) 1332–1336.
49) Jianxiang Wen*, Letian Liang.et al, Fabrication and characteristics of 1-type reduced diameter polarization maintaining optical fiber, Chinese Optics Letters, 2006, 9, 4 (9): 512-514.
50) 文雁平，文建湘*，赵鑫, 细径熊猫型PMF的特性研究，光纤与电缆及其应用技术, 2011.
会议论文
51) Yan Wu; Xinyu He; Jianxiang Wen*; Fufei Pang; Zhenyi Chen; Xianglong Zeng; Tingyun Wang,All-Fiber Second-Order OAM Amplifier Based on Mode Selective Coupler, CLEO2020, USA, STu3R.3.
52) Haihong Zhan and Jianxiang Wen*, Optical Gain Characteristics of Pb/Bi Co-doped Silica based Optical Fiber, CLEO2017, USA, AT.2017.JTu5A.118.
53) HaihongZhan, Jianxiang Wen*, Yanhua Dong, Yanhua Luo，Gang-ding Peng,Fufei Pang, Zhenyi Chen, and Tingyun Wang, Photoluminescence spectral characteristics of Pb/Bi co-doped silica fiber, Proc. of SPIE ,2016 APOS, 2016,10, Shanghai.
54) Jianxiang Wen*, Wenjun Liu,Yanhua Dong, et al., Spectral characteristics of Bi/Er co-doped silica fiber fabricated by atomic layer deposition (ALD), Asia Communications and Photonics Conference, HongKong, November, ACP 2015, New Perspective of Fibers.
55) Jianxiang Wen*, Wenna Wang, Y Yanhua Luo, Gangding Peng, Fufei Pang, Zhenyi Chen, Tingyun Wang, Magneto-optic properties of Pb/Al codoped silica fiber via atomic layer deposition, Proc. of SPIE, 2015 OFS, Brazil, Proc. of SPIE Vol. 9634, 96345G-1. doi: 10.1117/12.** ( EI: 20**4)
56) Jianxiang Wen*, Jie Wang, Wenjun Liu, et al., Influence of spin manufacturing process on properties of the spun single mode fiber[C], Proc. of SPIE, 2014 OFS, Spain, 9157: 91572E-1 9
57) Jianxiang Wen*,Jie Wang, Yanhua Dong, et al., Influence of Gamma-ray irradiation on the spectral properties of Bi-doped silica fibers, Asia Communications and Photonics Conference, Shanghai, China, November 11-14, ACP 2014, New Perspective of Fibers (Page ATh4C). (EI: 20**1)
58) Jianxiang Wen*, Pupu Wang, et al., Fabrication and Photoluminescence Property of the PbS-doped Silica Optical Fiber, CLEO2013, USA, JTu4A.15, 2013. 6
59) Jianxiang Wen*, Pupu Wang, Yanhua Dong, et al., Bismuth-doped silica fiber fabricated by atomic layer deposition doping technique, 2013ACP, AW4C.5.
60) Jianxiang Wen*, Gang-ding PENG and Tingyun WANG, Development on the Bismuth-doped Silica-based Optical Fibers, Proceeding of Joint Workshop on Frontier Photonic&Electronics, [6-9], Sydney, Australia, 4& 5 March 2010. ( Oral and Poster).

申请与授权发明专利：
1) 文建湘，刘正，王廷云等，有源微晶光纤的制备方法及装置，申请号：0.6，申请 日：2019年4月30日
2) 文建湘，陈丽君，王廷云等，一种提高铋相关掺杂光纤发光效率和荧光寿命的方法，申请号：1.0，申请 日：2019年4月30日
3) 文建湘，王廷云，董艳华等，一种Bi/Al共掺石英光纤及其制备方法，授权专利号:ZN 2015 1 **.8
4) 文建湘，王廷云，董艳华等，种Bi/Er或Bi/Er/Al共掺石英光纤及其制备方法，授权专利号:ZN 2015 1 **.3
5) 肖中银, 文建湘, 王廷云等，一种提高石英光纤抗辐射性能的处理方法,　授权专利号：ZL 2013 1 **.9.
6) 陈振宜，王廷云，庞拂飞，刘琳，文建湘，付兴虎，基于双锥形光纤渐逝波耦合的光纤拉曼传感检测装置，授权专利号：ZL 2009 1 **.5
7) 文建湘，王廷云，邢建飞等，一种涡旋光束模式转换耦合器及其制作方法，申请日期：2018.7.13，申请公布号：5.3
8) 文建湘，王廷云，董艳华等，一种用于涡旋光束传输保持的光纤及其制备方法，申请日期：2018.7.13，申请公布号：2.3.
9) 王廷云，陈振宜，陈娜, 庞拂飞，文建湘, 刘书鹏, 铌酸锂掺杂石英光纤,申请/专利号：CN6.8, 申请日期：2018-05-09, 公开/公告号：CNA.
10) 王廷云，文建湘，董艳华等，一种纳米半导体PbS掺杂石英放大光纤及其制备方法 ，申请日：2015.12.16，申请号：4.1，申请公布号：CN A
11) 陈振宜,王廷云, 庞拂飞, 文建湘, 陈娜,3D打印横截面结构几何形状任意的光纤预制棒制备方法 , 申请/专利号：CN0.0,申请日期：2015-11-18;公开/公告号：CNA;
12) 罗文芸, 李杨, 贾晓斌, 郭强, 孙欣欣, 宫仁祥, 文建湘, 肖中银, 陈振宜 王廷云, 用于放疗实时在体剂量监测的石英光纤剂量计, 申请/专利号：CN2.5; 申请日期：2015-09-02,公开/公告号：CNA

其他学术兼职：
2020 ACP（Asia Communications and Photonics Conference）TPC（Technical Program Committee Member ）；
上海市先进光波导智能制造与测试专业技术服务平台副主任；
上海市惯性技术学会副秘书长；
上海市2020年度“科技创新行动计划”科技型中小企业技术创新项目与优秀学术/技术带头人项目评审专家；
上海市科技专家库专家；
国家自然科学基金委员会（NSFC）信息学部函评专家；
美国电子工程IEEE会员；美国光学学会OSA 会员；
上海市欧美同学会澳新分会、上海大学分会理事；
多个国际学术期刊审稿人（IEEE/OSA Journal of Lightwave Technology，Photonics Research, Optics Letter, Optics Express，Journal of Applied Physics，Optics Fiber Technology, Applied Optics，Optics Communications，IEEE Transaction on Nuclear Science，Journal of Non-Crystalline Solids等）