吴涛

姓名：吴涛 职称：副教授 学校：武汉工程大学 联系方式：18186471984 邮件：wutao@wit.edu.cn

 

个人简介

吴涛，现任武汉工程大学光电信息与能源工程学院副教授，硕士生导师。获华中科技大学光学工程博士学位，获国家留学基金委全额资助于都柏林大学物理学院做博士后研究。

研究方向

激光等离子体物理、磁流体动力学非平衡演化与多孔介质流体力学。激光等离子体物理在LIBS技术、极紫外光刻机光源、水窗成像光源、激光精密加工、激光粒子加速器、激光推进、激光等离子体波导与激光核聚变等诸多领域有广泛的应用。在激光等离子体短波长光源研究领域，作为极紫外光刻机的心脏——激光等离子体极紫外光源的机理研究对提高光源转换效率，寻求新一代13.5纳米极紫外光刻光源的全新技术路线与解决方案具有重要意义。课题组对“卡脖子”的核心器件极紫外光刻机光源的极紫外辐射机理与等离子体特性进行了大量研究，并对超极紫外光刻光源的实现进行了一些原理性探索。在磁流体动力学非平衡演化与多孔介质流体力学方面也开展了相关研究。

 

学术成果

吴涛，武汉工程大学光电信息与能源工程学院副教授、硕士生导师。获国家留学基金委全额资助于都柏林大学物理学院做博士后研究，合作导师为13.5纳米极紫外光刻光源原理提出者、爱尔兰科学院院士Gerry O’Sullivan。主持国家自然科学基金项目 1 项、湖北省科研项目 2 项，主持广东省基础与应用基础重大项目1项等，科研进账200余万元，主编教材 2 本，发表教学科研论文 60 余篇，其中在国际权威期刊发表第一作者SCI/EI收录论文20余篇，担任Journal of Applied Physics、Journal of Physics B、Plasma Science and Technology、光学学报等国内外多种权威期刊审稿人。

 

代表性论文：

[1] T. Wu, S.F. Wang, A Fractal Permeability Model for Real Gas in Shale Reservoirs Coupled with Knudsen Diffusion and Surface Diffusion Effects, Fractals-Complex Geometry Patterns and Scaling in Nature and Society, 28(1) (2020).

[2] T. Wu, H. Kawasaki, Y. Shimada, T. Higashiguchi, G. O'Sullivan, Investigation of extreme ultraviolet spectra from highly charged holmium ions in 1 mu m laser-produced plasmas, Journal of Physics B-Atomic Molecular and Optical Physics, 53(22) (2020).

[3] T. Wu, J. He, L. Yang, P. Lu, A study on soft x-ray spectra from pulsed 1 μm Nd:YAG laser-induced ytterbium plasmas, Plasma Science and Technology, 22(10) (2020) 105503.

[4] T. Wu, J. He, S.F. Wang, C.H. Tang, Analysis of UTA Spectra of Nd : YAG Pulse Laser Produced Mo Plasmas, Spectrosc Spect Anal, 38(3) (2018) 692-696.

[5] T. Wu, T. Higashiguchi, B.W. Li, G. Arai, H. Hara, Y. Kondo, T. Miyazaki, T.H. Dinh, F. O'Reilly, E. Sokell, G. O'Sullivan, Analysis of unresolved transition arrays in XUV spectral region from highly charged lead ions produced by subnanosecond laser pulse, Optics Communications, 385 (2017) 143-152.

[6] T. Wu, T. Higashiguchi, B.W. Li, G. Arai, H. Hara, Y. Kondo, T. Miyazaki, T.H. Dinh, P. Dunne, F. O'Reilly, E. Sokell, G. O'Sullivan, Spectral investigation of highly ionized bismuth plasmas produced by subnanosecond Nd: YAG laser pulses, Journal of Physics B-Atomic Molecular and Optical Physics, 49(3) (2016).

[7] T. Wu, T. Higashiguchi, B.W. Li, Y. Suzuki, G. Arai, T.H. Dinh, P. Dunne, F. O'Reilly, E. Sokell, G. O'Sullivan, XUV spectral analysis of ns- and ps-laser produced platinum plasmas, Journal of Physics B-Atomic Molecular and Optical Physics, 48(24) (2015).

[8] T. Wu, T. Higashiguchi, B.W. Li, Y. Suzuki, G. Arai, T.H. Dinh, P. Dunne, F. O'Reilly, E. Sokell, L.N. Liu, G. O'Sullivan, Analysis of extreme ultraviolet spectra from laser produced rhenium plasmas, Journal of Physics B-Atomic Molecular and Optical Physics, 48(16) (2015).

[9] T. Wu, X.B. Wang, D.L. Zuo, P.X. Lu, Research of pulse CO2 Laser produced tin plasma, High-Power Laser Materials Processing: Lasers, Beam Delivery, Diagnostics, and Applications Ii, 8603 (2013).

[10] T. Wu, X.B. Wang, S.Y. Wang, Spectral Efficiency of Extreme Ultraviolet Emission from CO2 Laser-Produced Tin Plasma Using a Grazing Incidence Flat-Field Spectrograph, Plasma Sci Technol, 15(5) (2013) 435-438.

[11] T. Wu, X.B. Wang, S.C. Yu, L. Xiong, A Model for Extreme Ultraviolet Radiation Conversion Efficiency From Laser Produced Mass-Limited Tin-Based Droplet Target Plasmas, Commun Theor Phys, 57(4) (2012) 695-700.

[12] T. Wu, X.B. Wang, S.Y. Wang, J. Tang, P.X. Lu, H. Lu, Time and space resolved visible spectroscopic imaging CO2 laser produced extreme ultraviolet emitting tin plasmas, Journal of Applied Physics, 111(6) (2012).

[13] T. Wu, X.B. Wang, H. Lu, P.X. Lu, Debris mitigation power of various buffer gases for CO2 laser produced tin plasmas, J Phys D Appl Phys, 45(47) (2012).