職稱：特聘教授

學位：理學博士

研究方向：特種光纖制造技術、光纖激光、光通訊和光傳感

Email：weixuboston@hotmail.com

 

2003网站太阳集团學科領軍人才，特聘教授，國家特聘專家。澳大利亞悉尼大學光纖技術專業物理學博士。從事特種光纖材料機理研究、制造工藝開發和産品産業化20多年，其研發成果和産品獲得美國通用電氣公司GE、美國霍尼韋爾公司Honeywell、英國航天航空系統公司BAE Systems、瑞士ABB公司和日本三菱公司等全球頂尖企業的認可和批量采購。

教育背景

² 1995/10 - 1999/08，澳大利亞悉尼大學 University of Sydney，光纖技術物理博士

² 1992/09 - 1995/06，廈門大學，凝聚态理論物理，碩士

² 1988/09 - 1992/06，廈門大學，無線電物理，學士

工作經曆

Ø 2023/05 – 至今，2003网站太阳集团特聘教授，研究星空激光通訊核心激光光纖材料的耐輻照機理和制備。

Ø 2019/12 – 2023/05，武漢勝芯光電科技有限公司首席科學家，研發和生産填補國内空白、“卡脖子”的特種光纖。

Ø 2012/09 - 2019/10，中國兵器工業集團特聘首席專家、中國兵器工業集團武漢北方光電科技有限公司總經理。

Ø 2009/10 - 2012/08，美國國家宇航局NASA“太空飛行器液态燃料容量檢測和氫氣洩漏檢測項目”的第一負責人Principle Investigator。

Ø 2001/05 - 2009/10，美國最大激光器生産商Coherent公司特種光纖部（原StockerYale公司）Research Engineer (2001), Senior Research Engineer (2002 ~ 2004), Principle Scientist (2005 ~ 2009）。

Ø 1999/08 - 2001/05，University of Sydney光纖技術中心Postdoctoral Fellow (1999/08~2000/04), Research Fellow (2000/04 ~ 2001/05)。

榮譽和報道

Ø 2012年美國國家宇航局NASA提交給美國總統白宮辦公室的年度工作報告中彙報徐巍的研究成果

Ø 2012年美國國家宇航局NASA刊物The New Concept報道徐巍的研究成果

Ø 2010年獲美國國家宇航局NASA“發明和貢獻委員會”頒發的技術創新獎

國家級項目

Ø 2012，美國國家宇航局NASA Glen研究中心, 項目名稱“Fiber Optic Continuous Liquid Sensor for Cryogenic Propellant Gauging”, Phase 3。

Ø 2009 - 2011, 美國國家宇航局NASA肯尼迪航天中心, 項目名稱“In-Space Distributed Fiber Optic Hydrogen Leak Sensor”, Phase 2。 

Ø 2009, 美國國家宇航局NASA Glen研究中心, 項目名稱“Fiber Optic Continuous Liquid Sensor for Cryogenic Propellant Gauging”, Phase 1。

Ø 2008，美國國家宇航局NASA肯尼迪航天中心，項目名稱“In-Space Distributed Fiber Optic Hydrogen Leak Sensor”, Phase 1。

授權發明專利

Ø 2018，徐巍，張栓民，葉亞楠，王靜，“低損耗耐高溫光纖”，發明專利号：ZL201410400444.4。

Ø 2012, Wei Xu, "Method and Apparatus for Distributed Sensing Utilizing Optical Scattering in Optical Waveguides,” 美國專利号US 8,203,707 B2。 

Ø 2001, D. Wong, Wei Xu, P. Blazkiewicz, and T. Ryan, “Poled Waveguide Structure with Stabilised Internal Electric Field,” 國際專利号WO 01/31390。

Ø 2001 Wei Xu, D. Wong, G. Town, J. Canning, and P. Blazkiewicz, “Laser Assisted Thermal Poling of Silica Based Waveguides,” 國際專利号WO 01/20389）

期刊論文

1. X. Chi et al. “Fabrication of a Hydrogen Sensing Optical Fiber Using Atomic Layer Deposition”, IEEE Photonics Technology Letters, vol. 34, pp.687-690, July 2022.

2. X. Chi et al. “Optical Fiber–Based Continuous Liquid Level Sensor Based on Rayleigh Backscattering", Micromachines, 13, 633, 2022.

3. X. Chi, X. Ke and W. Xu, “Manufacturing Long Optical Fiber with Specialty Coatings for Distributed Sensing”, IEEE Photonics Technology Letters, vol. 31, pp.783-786, May 2019.

4. X. Chi, X. Ke and W. Xu, “Optical fibre liquid sensor for cryogenic propellant mass measurement,” IEE Electronics Letters, vol. 55, pp. 278-280, 2019.

5. W. Xu, Wenxin Zheng, Baozhong Liu, Brent Ware, Neal Zumovitch, “Fiber at the home: broadband communication and multiple sensing,” Invited Paper, Proceedings of SPIE, vol. 6784, 2007.

6. Y. Lin, P. Herman, W. Xu, “In-fiber colloidal photonic crystals and the formed stop band in fiber longitudinal direction,” Journal of Applied Physics, vol. 102, pp. 073106-073106-4, 2007.

7. Qiying Chen, Kevin P. Chen, W. Xu, and Suwas Nikumb, “Deep ultraviolet femtosecond laser tuning of fiber Bragg gratings,” Optics Communications, vol. 259, pp. 123-126, 2006.

8. Ben McMillen, Chuck Jewart, Michael Buric, W. Xu, Yuankun Lin, and Kevin P. Chen, “Fiber Bragg Grating Vacuum Sensors,” Applied Physics Letters, vol. 87, 234101, 2005.

9. Kevin P.  Chen, Ben McMillen, Michael Buric, Chuck Jewart, W. Xu, “Self-Heated Fiber Bragg Grating Sensors,” Applied Physics Letters, vol. 86, 143502, 2005.

10. Chen, K.P., Cashdollar, L.J., W. Xu, “Controlling fiber Bragg grating spectra with in-fiber diode laser light,” IEEE Photonics Technology Letters, vol. 16, pp.1897-1899, Aug. 2004

11. P. Blazkiewicz, W. Xu, and S. Fleming, “Optimum parameters for CO₂ laser-assisted poling of optical fibers,” Journal of Lightwave Technology, vol. 20, pp. 965-968, June 2002.

12. P. Blazkiewicz, W. Xu, and S. Fleming, “Mechanism for thermal poling in twin-hole silicate fibers,” Journal of Optical Society of America, Part B, vol. 19, pp. 870-874, April 2002.

13. P. Blazkiewicz, W. Xu, D. Wong, S. Fleming, and T. Ryan, “Modification of Thermal Poling Evolution Using Novel Twin-Hole Fibers,” Journal of Lightwave Technology, vol. 19, pp. 1149-1154, August 2001.

14. W. Xu, P. Blazkiewicz, and S. Fleming, “Silica Fibre Poling Technology,” Advanced Materials, vol. 12-13, pp. 1014-1018, July 2001.

15. P. Blazkiewicz, W. Xu, S. Fleming, “Modification of the Third-Order Nonlinearity in Poled Silica Fibers,” Proceedings of SPIE, vol. 4216, Optical Devices for Fiber Communication II, pp. 129-138, February 2001.

16. W. Xu, P. Blazkiewicz, D. Wong, S. Fleming and T. Ryan, “Specialty Optical Fibre for Stabilizing and Enhancing Electro-optic Effect Induced by Poling,” IEE Electronics Letters, vol. 36, pp. 1265-1266, 2000.

17. W. Xu, D. Wong, S. Fleming, and P. Blazkiewicz, “Electrically Tunable Thermally-Poled Bragg Gratings,” Optical Society of America, Trends in Optics and Photonics (TOPS), vol. 33, Bragg Gratings, Photosensitivity, and Poling in Glass Waveguides, pp. 363 – 367, 2000.

18. P. Blazkiewicz, W. Xu, D. Wong, J. Canning, M. Aslund, and Graham Town, “Experimental Demonstration of Carbon-Dioxide Laser Assisted Poling of Optical Fibers,” Optical Society of America, Trends in Optics and Photonics (TOPS), vol. 33, Bragg Gratings, Photosensitivity, and Poling in Glass Waveguides, pp. 393 – 396, 2000.

19. W. Xu, D. Wong, S. Fleming, and P. Blazkiewicz, “Evolution of Charge Layers during Thermal Poling of Silica Fibres,” Optical Society of America, Trends in Optics and Photonics (TOPS), vol. 33, Bragg Gratings, Photosensitivity, and Poling in Glass Waveguides, pp. 414 – 418, 2000.

20. P. Blazkiewicz, W. Xu, D. Wong, J. Canning, M. Aslund, and G. Town, “Carbon-Dioxide Laser-Assisted Poling of Silicate Optical Fibers,” OSA Optics Letters, vol. 25, pp. 200-202, 2000.

21. W. Xu, J. Arentoft, D. Wong, and S. Fleming, "Evidence of space-charge effects in thermal poling," IEEE Photonics Technology Letters, vol. 11, pp. 1265-1267, 1999.

22. D. Wong, W. Xu, and S. Fleming, “Charge dynamics and distributions in thermally poled silica fibre,” Proceedings of SPIE, vol. 3847, pp. 88-93, 1999.

23. W. Xu, M. Janos, D. Wong, and S. Fleming, "Thermal poling of boron-doped germano-silicate fibre," Japan IEICE Transactions on Communications, vol. E82-B, pp. 1283-1286, 1999, and Japan IEICE Transactions on Electronics, vol. E82-C, pp. 1549-1552, 1999.

24. W. Xu, D. Wong, and S. Fleming, “Evolution of the linear electro-optic coefficients and the third order nonlinearity in prolonged negative thermal poling,” IEE Electronics Letters, vol. 35, pp. 922-923, 1999.

25. M. Janos, W. Xu, D. Wong, H. G. Inglis and S. Fleming, "Growth and decay of the electro-optic effect in thermally poled B/Ge co-doped fibre," IEEE Journal of Lightwave Technology, vol. 17, pp. 1037-1041, 1999.

26. D. Wong, W. Xu, and S. Fleming, “Dynamics of frozen-in fields in germanosilicate fibres during thermal poling,” Optical Society of America, Trends in Optics and Photonics (TOPS), vol. 29, WDM Components, pp. 278 - 285 1999.

27. D. Wong, W. Xu, S. Fleming, M. Janos, and K. M. Lo, "Frozen-in field in thermally poled fibres," Optical Fiber Technology, vol. 5, pp. 235-241, 1999.

28. D. Wong, W. Xu, S. Fleming and M. Janos, “Recent results with thermal poling of fibre,” Proceedings of SPIE, vol. 3542, pp. 120-123, 1998.

29. D. Wong, W. Xu, M. Janos, J. Chow, R. Hall, and S. Fleming, "Time evolution of electro-optic effect in fibre during thermal poling," Japanese Journal of Applied Physics, vol. 37, suppl. 37-1, pp. 68-70, 1998.

30. S. Fleming, D. Wong, H.G. Inglis, W. Xu, T. Fujiwara and P. Hill, "Poled fibre devices for electro-optic modulation", Invited paper, Proceedings of SPIE, vol. 2893, pp. 450-460, 1996.