联系我们 宁波材料所
郭伟

姓  名:

郭伟

所在单位:

中国科学院宁波材料技术与工程研究所

职  称:

研究员

邮寄地址:

浙江省宁波市镇海区中官西路1219

办公电话:

 

电子邮件:

guowei123@ nimte.ac.cn

办公地点:

M503

教育背景

1998.09-2002.06 天津理工大学 本科学习 学士学位

2003.09-2004.12 英国曼彻斯特大学 硕士学习 硕士学位

2005.09-2009.12 英国曼彻斯特大学 博士学习 博士学位

工作履历

2010.06-2013.01 英国曼彻斯特大学激光加工研究中心 助理研究员

2013.01-2022.11 英国曼彻斯特大学激光加工研究中心 研究员

2022.12- 至今 中国科学院宁波材料技术与工程研究所 研究员

   

 

学术兼职

 

研究领域

激光微纳加工及超分辨率光学技术

研究概况

长期从事激光加工应用研究,在激光微纳制造及超分辨率光学技术领域取得了系列研究成果。在国际期刊上发表论文50余篇,包括Applied Physics Letters, Nature Communications, Light: Science & Applications 等期刊;授权国际专利2项;主持和参与多个英国工程和自然科学基金国家项目、英国创新署重点专项以及国际联合研发计划专项。

学术成果

出版著作:

 

发表文章:

1. Wei Guo, Zengbo Wang, Lin Li, David J Whitehead, Zhu Liu, Boris Luk'yanchuk, Nearfield laser parallel nanofabrication of arbitrary-shaped patterns, Applied Physics Letters, 2007, 90/24/243101,

2. Wei Guo, Zengbo Wang, Lin Li, Zhu Liu, Boris Luk'yanchuk , David J Whitehead, Chemical-assisted laser parallel nanostructuring of silicon in optical near fields, Nanotechnology, 2008, 19/45/455302

3. Wei Guo, Zengbo Wang, Lin Li, Z. Liu, Zhu Liu, Boris Luk'yanchuk , David J Whitehead, Philip Crouse, Laser parallel nanopatterning of lines and curves by micro-particle lens arrays, Journal of Laser Micro/Nano Engineering, 2007, 2/3/P212-215

4. Wang ZB, Guo W, Li L, et al. Optical virtual imaging at 50 nm lateral resolution with a white-light nanoscope. Nature Communications. 2011; 2.

5. Li L, Guo W, Yan YZ, Lee S, Wang T. Label-free super-resolution imaging of adenoviruses by submerged microsphere optical nanoscopy. Light-Science & Applications. 2013; 2.

6. Wei C, Guo W, et al. Understanding the behavior of workpiece’s bulk temperature during laser assisted turning of Ti6Al4V alloy and heating of Al-SiC metal matrix composite rods,. Optics and Laser Technology, 2021, V139, 106951

7.  Li ZL, Allegre O, et al. Femtosecond laser single step, full depth cutting of thick silicon sheets with low surface roughness. Optics and Laser Technology, 2021, V138, 106899

8. Li ZQ, Wang XF, Wang JL, et al. Stealth dicing of sapphire sheets with low surface roughness, zero kerf width, debris/crack-free and zero taper using a femtosecond Bessel beam. Optics & Laser Technology. 2021; V135, 106713

9. Chen Q, Guo W, et al. Ultrafast and Scalable Laser-Induced Crystallization of Titanium Dioxide Films for Planar Perovskite Solar Cells. SOLAR RRL, 2021, V5,1, 2000562

10. Wei C, Guo W, et al. High speed, high power density laser-assisted machining of AlSiC metal matrix composite with significant increase in productivity and surface quality. Journal of Materials Processing Technology. 2020; V285,116784

11. Sun Z, Guo W, Li L. Numerical modelling of heat transfer, mass transport and microstructure formation in a high deposition rate laser directed energy deposition process. Additive Manufacturing. 2020; V33, 101175

12. Sun Z, Guo W, Li L. In-process measurement of melt pool cross-sectional geometry and grain orientation in a laser directed energy deposition additive manufacturing process. Optics and Laser Technology. 2020; V129, 106280

13. Li ZQ, Wang JL, Wang XF, et al. Debris-free, Zero Taper Cutting of BOROFLOAT 33 Glass Using a Femtosecond Bessel Laser Beam. Lasers in Engineering. 2020; 46(5-6): P383-93.

14. Li ZQ, Guo W, Allegre O, et al. Debris-free Cutting of Quartz with Zero Kerf Width and Ultra-low Surface Roughness Using Femtosecond Bessel Laser Beam Filamentation. Lasers in Engineering. 2020; 46(5-6): P343-57.

15. Li ZQ, Allegre O, Guo W, et al. Ultrafast Laser Drilling of Crack-free, Debris-free and Heat Affected Zone (HAZ)-free Blind Holes in Al2O3 with Flat Bottom and Reduced Taper Angles. Lasers in Engineering. 2020; 46(5-6): P367-81.

16. Huang YH, Sepioni M, Whitehead D, et al. Rapid growth of large area graphene on glass from olive oil by laser irradiation. Nanotechnology. 2020; 31(24), 245601

17. Zhang SL, Suebka C, Liu H, et al. Mechanisms of laser cleaning induced oxidation and corrosion property changes in AA5083 aluminum alloy. Journal of Laser Applications. 2019; 31(1).

18. Kuang Z, Guo W, Li JN, et al. Nanosecond fibre laser paint stripping with suppression of flames and sparks. Journal of Materials Processing Technology. 2019; 266:474-83.

19. Zhang FD, Liu H, Suebka C, et al. Corrosion behaviour of laser-cleaned AA7024 aluminium alloy. Applied Surface Science. 2018; 435: P452-61.

20. Huang YH, Zeng L, Liu CG, et al. Laser Direct Writing of Heteroatom (N and S)-Doped Graphene from a Polybenzimidazole Ink Donor on Polyethylene Terephthalate Polymer and Glass Substrates. Small. 2018; 14(44),1803143

21. Hadi A, Alhabradi M, Chen Q, et al. Rapid fabrication of mesoporous TiO2 thin films by pulsed fibre laser for dye sensitized solar cells. Applied Surface Science. 2018; 428:1089-97.

22. Feng JC, Rathod DW, Roy MJ, et al. An evaluation of multipass narrow gap laser welding as a candidate process for the manufacture of nuclear pressure vessels. International Journal of Pressure Vessels and Piping. 2017; 157: P43-50.

23. Feng JC, Guo W, Irvine N, Li L. Understanding and elimination of process defects in narrow gap multi-pass fiber laser welding of ferritic steel sheets of 30 mm thickness. International Journal of Advanced Manufacturing Technology. 2017; 88(5-8):1821- 1830.

24. Shen XF, Li L, Guo W, Teng WH, He WP. Comparison of processing window and porosity distribution in laser welding of 10 mm thick 30CrMnSiA ultrahigh strength between flat (1G) and horizontal (2G) positions. Journal of Laser Applications. 2016; 28(2), 022418

25. Feng JC, Guo W, Francis J, Irvine N, Li L. Narrow gap laser welding for potential nuclear pressure vessel manufacture. Journal of Laser Applications. 2016; 28(2), 022421

26. Dong SY, Guo W, Francis JA, Li L. Microstructure and mechanical characteristics of a laser welded joint in SA508 nuclear pressure vessel steel. Materials Science and Engineering a-Structural Materials Properties Microstructure and Processing. 2015; 625:65-80.

27. Yan YZ, Li L, Feng C, Guo W, Lee S, Hong MH. Microsphere-Coupled Scanning Laser Confocal Nanoscope for Sub-Diffraction-Limited Imaging at 25 nm Lateral Resolution in the Visible Spectrum. Acs Nano. 2014; 8(2):1809-16.

28. Lee S, Li L, Wang ZB, Guo W, Yan YZ, Wang T. Immersed transparent microsphere magnifying sub-diffraction-limited objects. Applied Optics. 2013; 52(30): P7265-70.

29. Lee S, Li L, Ben-Aryeh Y, Wang ZB, Guo W. Overcoming the diffraction limit induced by microsphere optical nanoscopy. Journal of Optics. 2013; 15(12). 125710

30. Yue LY, Wang ZB, Guo W, Li L. Axial laser beam cleaning of tiny particles on narrow slot sidewalls. Journal of Physics D-Applied Physics. 2012; 45(36), 365106

31. Li L, Guo W, Wang ZB, Liu Z, Whitehead D, Luk'yanchuk B. Large-area laser nanotexturing with user-defined patterns. Journal of Micromechanics and Microengineering. 2009; 19(5). 054002

32. Wang ZB, Luk'yanchuk BS, Guo W, et al. The influences of particle number on hot spots in strongly coupled metal nanoparticles chain. Journal of Chemical Physics. 2008; 128(9). 094705

33. Wang ZB, Guo W, Pena A, et al. Laser micro/nano fabrication in glass with tunablefocus particle lens array. Optics Express. 2008; 16(24):19706-19711.

34. Wang ZB, Guo W, Lukyanchuk B, Whitehead DJ, Li L, Liu Z. Optical Near-field Interaction between Neighbouring Micro/Nano-Particles. Journal of Laser Micro Nanoengineering. 2008; 3(1):14-8

申请专利:

1. Sorin Stanescu; Wei Guo; Lin Li ; SCANNING MICROSPHERE LENS NANOSCOPE, 2018-01-18, WIPO,WO2018011583A3

2. Sorin Stanescu; Wei Guo; Lin Li ; Objective lens attachment, 2018-01-18, WIPO, WO2018011582A1