张雅-亚博888

姓名:张雅

性别:女

出生年月:1984年05月

职称/职务:教授/省部级人才

学位/学历:博士/研究生

硕/博生导师:硕导、博导

亚博888的联系方式:yazhang@whut.edu.cn

研究方向: 等离子体物理理论与数值模拟; 凝聚态物理理论;

教育背景与工作经历:

2016.06-今，武汉理工大学，理学院物理系，教授，博士生导师

2016.06-2021.10，武汉理工大学，理学院物理系，副教授，硕士生导师

2013/10-2015/10，比利时安特卫普大学，化学系，博士后

2013.07-2016.05，华中科技大学，物理学院，博士后

2010.09-2013.06，大连理工大学，等离子体物理，博士

主要教学科研成果:

1.主要从事等离子体物理的解析理论和数值模拟研究，包括量子等离子体和经典等离子体两个领域。前者包括与离子束驱动的惯性约束聚变相关的高能量密度物理、温稠密物质(warm dense matter, wdm) 等方向，采用量子流体动力学(quantum hydrodynamics, qhd) 模型，以线性解析理论和非线性数值模拟相结合的方法。后者包括磁约束聚变中的托卡马克启动过程，低温等离子体中的微等离子体、介质阻挡放电、容性耦合等离子体、气体击穿等问题，主要采用particle-in-cell/monte carlo (pic/mc) 模型。

2.已经在plasma sources science and technology，journal of applied physics等国际高水平刊物上发表第一作者或通讯作者60多篇，最近2年课题组每年发表10篇论文以上。与比利时鲁汶大学、安特卫普大学等国外高校，以及国内华中科技大学等单位都建立了广泛和深入的学术联系。

主要科研项目:

1. 国家自科基金面上项目, 重离子束驱动温稠密物质的pic/mc/qhd混合模拟研究

2. 国家自科基金面上项目, 微等离子体放电模式和模式转换的动理学研究

学术兼职:

中国电工技术学会等离子体及应用专业委员会委员(2021年至今);

中国核学会计算物理分会理事(2023-2028);

教育部学位中心博士、硕士和博士论文评阅人;

plasma sources science and technology、physics of plasmas等杂志评阅人

近2年发表文章列表:

[1] q. wang, h. wu, y. wang, y. zhang, w. jiang, and y. zhang, “influence 

of pulse width on the breakdown process of nanosecond pulse discharge at low pressure”, journal of physics d: applied physics 56, 465201 (2023)

[2] y. chen, x. jiang, l. yao, w. jiang, h. liu, and y. zhang, “electron scattering cross sections from nh3: a comprehensive study based on r-matrix method”, plasma sources science and technology 32, 045017 (2023)

[3] z. chen, z. chen, w. jiang, l. guo, and y. zhang, “line intensity calculation of laser-induced breakdown spectroscopy during plasma expansion in nonlocal thermodynamic equilibrium”, optics letters, 10.1364/ol.488250 (2023)

[4] y. zhang, f. zhai, and w. jiang, “valley-hall alternatively changing conductivity in gapped and strained graphene”, optics letters 48, 1998–2001 (2023)

[5] y. zhang, f. zhai, and w. jiang, “valley-dependent conductivity and dispersion relation of surface magnetoplasmons”, applied surface science 619, 156717 (2023)

[6] l. chen, h. wu, z. chen, y. wang, l. yi, w. jiang, and y. zhang, “note on particle balance in particle-in-cell/monte carlo model and its implications on the steady-state simulation”, plasma sources science and technology 32, 034001 (2023)

[7] x. li, h. wu, y. zhong, c. guo, l. yi, w. jiang, and y. zhang, “breakdown mode and parameter space of micro-discharge sustained by thermionic emission”, journal of physics d: applied physics 56, 175202 (2023)

[8] s. yu, h. wu, j. xu, y. wang, j. gao, z. wang, w. jiang, and y. zhang, “a generalized external circuit model for electrostatic particle-in-cell simulations”, computer physics communications 282, 108468 (2023)

[9] y. zhang, y. wang, j. xu, c. guo, w. jiang, and y. zhang, “numerical characterization of dual radio frequency micro-discharges”, aip advances 13, 035111 (2023)

[10] w. jiang, h. wu, z. wang, l. yi, and y. zhang, “gas breakdown in radio-frequency field within mhz range: a review of the state of the art”, plasma science and technology 24, 124018 (2022)

[11] z. chen, j. xu, s. yu, h. wu, x. huang, z. wang, l. guo, w. jiang, and y. zhang, “numerical simulations of the effects of radiofrequency cables on the single-frequency capacitively coupled plasma”, physics of plasmas 29, 113507 (2022) (editor’s pick)

[12] s. yu, z. chen, h. wu, l. guo, z. wang, w. jiang, and y. zhang, “best impedance matching seeking of single-frequency capacitively coupled plasmas by numerical simulations”, journal of applied physics 132, 083302 (2022) (cover and editor’s pick)

[13] l. chen, y. wang, y. jia, x. yang, c. li, l. yi, w. jiang, and y. zhang, “effect of viscosity on stopping power for a charged particle moving above two-dimensional electron gas”, laser and particle beams 2022, e6903026 (2022)

[14] y. zhou, y. wang, h. wu, y. zhang, w. jiang, and g. lapenta, “numerical characterization of capacitively coupled plasmas modulated by ion beam injection”, plasma sources science and technology 31, 045028 (2022)

[15] x. jiang, h. liu, y. zhang, w. jiang, m. ayouz, and v. kokoouline, “cross sections for vibrational excitation and dissociative recombination of the cf3 ion in collisions with low-energy electrons”, plasma sources science and technology 31, 045016 (2022)

[16] y. wang, y. zhou, h. wu, y. zhang, w. jiang, and g. lapenta, “computational study of microdischarges driven by electron beam injection with particle-in-cell/monte carlo collision simulations”, journal of applied physics 131, 163301 (2022) (editor’s pick)

[17] h. wu, z. chen, z. wang, b. rao, w. jiang, and y. zhang, “on the breakdown process of capacitively coupled plasma in carbon tetrafluoride”, journal of physics d: applied physics 55, 255203 (2022) (cover and editor’s pick)

[18] h. wu, z. chen, s. yu, q. wang, x. li, w. jiang, and y. zhang, “the effects of match circuit on the breakdown process of capacitively coupled plasma driven by radio frequency”, journal of applied physics 131, 153301 (2022)

[19] h. wu, z. chen, l. yi, w. jiang, and y. zhang, “note on the energy transport in capacitivelycoupled plasmas”, plasma sources science and technology 31, 047001 (2022)

[20] y. zhong, h. wu, x. li, j. gao, w. jiang, y. zhang, and g. lapenta, “numerical characterization of the breakdown process of dc-driven micro-discharges sustained by thermionic emission”, journal of physics d: applied physics 55, 215203 (2022)

[21] x. zuo, y. zhou, q. zhang, h.-y. wang, z. li, j. zhu, x. jiang, and y. zhang, “two-dimensional particle-in-cell/monte carlo simulations of streamer formation and propagation in catalyst pores in a surface dielectric barrier discharge”, plasma processes and polymers n/a, e2200025 (2022)

[22] j. gao, s. yu, h. wu, y. wang, z. wang, y. pan, w. jiang, and y. zhang, “self-consistent simulation of the impedance matching network for single frequency capacitively coupled plasma”, journal of physics d: applied physics 55, 165201 (2022)