您的当前位置:首页 > 师资队伍
吴淑群
姓名: 吴淑群 性别: 职务:
职称: 副教授 导师类别: 硕士生导师 办公室: 电气楼506
研究领域: 面向国家电网和国防单位的战略需求,培养电力行业专业人才。
主要研究领域:
1)高频高功率脉冲电源技术
2)电气设备智能状态监测与故障诊断。
3)高电压放电航空航天应用
电话: 13305143147 Email: wushuqun@nuaa.edu.cn
个人简介

1)教育经历:

2006-2010,本科毕业于华中科技大学,电气工程专业;

2010-2015,博士毕业于华中科技大学,研究方向为高压纳秒脉冲放电与等离子体应用;

2015-至今,就职于南京航空航天大学。

2)学术兼职:

IEEE member,电工技术学会高级会员

担任Phys. Plasma, IEEE Trans. Plasma Sci. , Plasmas Science and Technology,电工技术学报,高电压技术期刊审稿人。

国家自然科学基金通讯评审专家;

教育部学位论文评审专家;

《大百科全书》电工词条撰写;

每年招收2名硕士研究生,邮箱wushuqun@nuaa.edu.cn

学术成果

1)自动化学院优秀青年骨干教师

2)发表SCI期刊论文36篇(第一作者21篇),他引次数450余次。

3)在2015年ICOPS和2016年SACT国际会议上做特邀报告。

1. Journal Papers

[38] Yan Lu, Shuqun Wu*, Wenxin Cheng, Xinpei Lu, Electric field measurements in atmospheric-pressure microplasma jet using Stark polarization emission spectroscopy of helium atom, Eur. Phys. J. Special Topics, DOI:10.1140/epjst/e2016-60334-7, accepted.

[37] 吴淑群,董熙,裴学凯,岳远富,卢新培,基于激光诱导荧光法诊断大气压低温等离子体射流中OH自由基和O原子的时空分布 ,电 工 技 术 学 报,2017, 32(8):82-96.

[36] Wu S, Gou J, Lu X, Tang M. A 3.4-μm-Sized Atmospheric-Pressure non-equilibrium microplasma array with high aspect ratio and high electron density[J]. IEEE Transactions on Plasma Science, 2016,44, 2632-2637.

[35] Wu S, Lu X, Yue Y, Dong X, and Pei X. Effects of the tube diameter on the propagation of helium plasma plume via electric field measurement, Physics of Plasmas 23, 103506 (2016)

[34] Wu S, Cao Y, Lu X. The State of the Art of Applications of Atmospheric-Pressure Nonequilibrium Plasma Jets in Dentistry[J]. IEEE Transactions on Plasma Science, 2016,44(2):134-151.

[33] Wu S, Duan J, Lu X. Effects of N-2/O-2 Additives on the Repeatability of the Dynamics of an Atmospheric-Pressure He Plasma Jet[J]. IEEE Transactions on Plasma Science, 2016,44(4SI1):398-404.

[32] 吴淑群,聂兰兰,卢新培. 大气压非平衡等离子体射流[J]. 高电压技术, 2015(08):2602-2624.

[31] Wu S, Xu H, Xian Y, et al. Propagation of plasma bullet in U-shape tubes[J]. AIP Advances, 2015,5(0271102).

[30] Wu S, Lu X. The role of residual charges in the repeatability of the dynamics of atmospheric pressure room temperature plasma plume[J]. Physics of Plasmas, 2014,21(12350912).

[29] Wu S, Lu X. Two counter-propagating He plasma plumes and ignition of a third plasma plume without external applied voltage[J]. Physics of Plasmas, 2014,21(0235012).

[28] Wu S, Lu X, Liu D, et al. Photo-ionization and residual electron effects in guided streamers[J]. Physics of Plasmas, 2014,21(10350810).

[27] Wu S, Lu X, Pan Y. On the mechanism of acceleration behavior of plasma bullet[J]. Physics of Plasmas, 2014,21(0735097).

[26] Wu S, Wang Z, Huang Q, et al. Dynamics of Mode Transition in Air Dielectric Barrier Discharge by Controlling Pressures[J]. IEEE Transactions on Plasma Science, 2014,42(10SI1):2342-2343.

[25] Wu S, Huang Q, Wang Z, et al. On the magnetic field signal radiated by an atmospheric pressure room temperature plasma jet[J]. Journal of Applied Physics, 2013,113(0433054).

[24] Wu S, Lu X, Pan Y. Effects of seed electrons on the plasma bullet propagation[J]. Current Applied Physics, 2013,131(SI):S1-S5.

[23] Wu S, Lu X, Zou D, et al. Effects of H-2 on Ar plasma jet: From filamentary to diffuse discharge mode[J]. Journal of Applied Physics, 2013,114(0433014).

[22] Wu S, Wang Z, Huang Q, et al. Atmospheric-pressure plasma jets: Effect of gas flow, active species, and snake-like bullet propagation[J]. Physics of Plasmas, 2013,20(0235032).

[21] Wu S, Xu H, Lu X, et al. Effect of Pulse Rising Time of Pulse dc Voltage on Atmospheric Pressure Non-Equilibrium Plasma[J]. Plasma Processes and Polymers, 2013,10(2):136-140.

[20] Wu S, Wang Z, Huang Q, et al. Open-air direct current plasma jet: Scaling up, uniformity, and cellular control[J]. Physics of Plasmas, 2012,19(10350310).

[19] Wu S, Zhan W, QuanJun H, et al. Study on a Room-Temperature Air Plasma for Biomedical Application[J]. IEEE Transactions on Plasma Science, 2011,39(6):1489-1495.

[18] Wu S, Huang Q, Wang Z, et al. The Effect of Nitrogen Diffusion From Surrounding Air on Plasma Bullet Behavior[J]. IEEE Transactions on Plasma Science, 2011,39(11SI1):2286-2287.

[17] Wu S, Lu X P, Ostrikov K, et al. Solitary filamentary structures and nanosecond dynamics in atmospheric-pressure plasmas driven by tailored dc pulses[J]. Applied Physics Letters, 2011,99(16150316).

[16] Wu S, Wang Z, Huang Q, et al. Plasma Plume Ignited by Plasma Plume at Atmospheric Pressure[J]. IEEE Transactions on Plasma Science, 2011,39(11SI1):2292-2293.

[15] Wu S, XinPei L, ZiLan X, et al. A touchable pulsed air plasma plume driven by DC power supply[J]. IEEE Transactions on Plasma Science, 2010,38(12):3404-3408.

[14] Pei X, Ghasemi M, Xu H, Wu S, et al. Dynamics of the gas flow turbulent front in atmospheric pressure plasma jets[J]. Plasma Sources Science and Technology, 2016,25(3):35010-35013.

[13] Pei X, Wang Z, Huang Q, Wu S, et al. Electron Avalanche Assisted by Preionization of Electron Beam in Ar[J]. IEEE Transactions on Plasma Science, 2014,42(10SI1):2396-2397.

[12] Pei X, Wu S, Xian Y, et al. On OH Density of an Atmospheric Pressure Plasma Jet by Laser-Induced Fluorescence[J]. IEEE Transactions on Plasma Science, 2014,42(51):1206-1210.

[11] Lu X, Wu S, Gou J, et al. An atmospheric-pressure, high-aspect-ratio, cold micro-plasma[J]. Scientific Reports, 2014,4(7488).

[10] Ye D, Wu S, Yu Y, et al. Patterned graphene functionalization via mask-free scanning of micro-plasma jet under ambient condition[J]. Applied Physics Letters, 2014,104(10310510).

[9] Zhang P, Wu S, Tan X, et al. A Novel Room-Temperature Air Plasma Jet Array Driven by DC Power Supply[J]. IEEE Transactions on Plasma Science, 2014,42(10SI1):2460-2461.

[8] Lu X, Wu S. On the Active Species Concentrations of Atmospheric Pressure Nonequilibrium Plasma Jets[J]. IEEE Transactions on Plasma Science, 2013,41(83):2313-2326.

[7] Pei X, Lu Y, Wu S, et al. A study on the temporally and spatially resolved OH radical distribution of a room-temperature atmospheric-pressure plasma jet by laser-induced fluorescence imaging[J]. Plasma Sources Science & Technology, 2013,22(0250232).

[6] Xian Y, Wu S, Wang Z, et al. Discharge Dynamics and Modes of an Atmospheric Pressure Non-Equilibrium Air Plasma Jet[J]. Plasma Processes and Polymers, 2013,10(4):372-378.

[5] Xian Y, Zhang P, Lu X, Pei X, Wu S, et al. From short pulses to short breaks: exotic plasma bullets via residual electron control[J]. Scientific Reports, 2013,3(1599).

[4] Xian Y, Lu X, Liu J, Wu S, et al. Multiple plasma bullet behavior of an atmospheric-pressure plasma plume driven by a pulsed dc voltage[J]. Plasma Sources Science & Technology, 2012,21(0340133).

[3] Xian Y, Lu X, Wu S, et al. Are all atmospheric pressure cold plasma jets electrically driven?[J]. Applied Physics Letters, 2012,100(12370212).

[2] Lu X, Wu S, Chu P K, et al. An atmospheric-pressure plasma brush driven by sub-microsecond voltage pulses[J]. Plasma Sources Science & Technology, 2011,20(0650096).

[1] Pei X, Wang Z, Huang Q, Wu S, et al. Dynamics of a Plasma Jet Array[J]. IEEE Transactions on Plasma Science, 2011,39(11SI1):2276-2277.

2. Conference Paper

[11] Shuqun Wu, Xinpei Lu, Chaohai Zhang*, The development of atmospheric-pressure plasmas jet (APPJ) sources for biomedical applications, SACT 2016, Danang, Vietnam. (Plenary)

[10] 吴淑群,卢新培, 介质管径大小对大气压低温等离子体的物理特性影响研究, 大气压等离子体及其应用研讨会 2016, 合肥 (oral)

[9] 吴淑群,卢新培, 利用He谱线的斯塔克分裂效应测量低温等离子体射流的电场强度, 全国高电压与放电等离子体学术会议,北京,25-27, 11, 2016 (oral,优秀口头报告)

[8] Shuqun Wu, Xi Dong, Jianmin Gou, Xinpei Lu, Atmospheric-pressure microplasmas with high aspect ratio and high electron density, IWPEEA-2016, Liverpool, UK, 21st -24th August 2016. (oral)

[7] Wu S, Lu X, Atmospheric-pressure microplasmas with high aspect ratio and high electron density, The 13th Asia-Pacific Conference on Plasma Science and Technology, 19-22 May, 2016, Shanghai, China. (oral)

[6] 吴淑群,卢新培,大气压低温等离子体射流中背景电荷效应机制研究,第十七届全国等离子体科学技术会议,成都 2015. (oral)

[5] 吴淑群、卢新培,双等离子体射流正对推进与无外加电压条件下第三次放电,中国电机工程学会高电压专业委员会2015年学术年会,中国 • 西安 (oral,优秀论文)

[4] Wu S, Lu X, The role of photo-ionization and residual electrons in atmospheric pressure nonequilibrium plasma jets,2015 42nd IEEE International Conference on Plasma Science (ICOPS)24-28 May 2015, Antalya, Turkey,2015.5.24-2015.5.28。(Invited talk)

[3] Wu S, Lu X,, Room Temperature Direct Current Air Plasma Jet for Biomedical Applications,2013 IEEE 40th International Conference on Plasma Sciences,2013.6.16-2013.6.21。(oral)

[2] Wu S, Lu X, On plasma bullet propagation: The role of seed electrons, The 7th international workshop on microplasmas (PeKing), 2013. (poster)

[1] Wu S, Lu X, Atmospheric plasma brush driven by sub-microsecond voltage pulses, IEEE Plasma Science Conference, Edinburgh in UK, 2012. (oral)

专利

1、一种人体可直接触摸的低温等离子体的产生方法, 公开号:CN101925246A,2010.12.22

2、一种人体可直接触摸的低温等离子体的产生装置, 公开号:CN201789680U,2011.04.06

承担项目

主持“极微等离子体射流的放电机理与化学活性研究”国家自然科学青年基金,2016

主持"大气压高长径比、高密度极微等离子体的纳秒放电机理研究" 江苏省自然科学青年基金,2016

主持校引进人才科研启动基金,2015年

参与“等离子体与气流相互作用软件开发”国家自然科学基金委的重大研究计划‘空天飞行器的若干重大基础问题’,2015

参与“大气压辉光放电激发态氧原子产生机制的研究”国家自然科学基金,2011

参与“等离子体隐身软件开发”国家安全重大基础研究项目,2010


版权所有@2016-南京航空航天大学·自动化学院 | 地址:江苏省南京市江宁区将军大道29号 | 邮政编码: 211106 电话:(025)84892368