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    周佩珩

    • 教授 博士生导师 硕士生导师
    • 毕业院校 : 电子科技大学
    • 学历 : 博士研究生毕业
    • 学位 : 工学博士学位
    • 所在单位 : 电子科学与工程学院(示范性微电子学院)

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    个人简介

      2003年至2009年在电子科技大学硕博连读,师从邓龙江教授。200912月获得博士学位,专业材料物理与化学。 2007年至2008年,获得首批国家留学基金委联合培养项目资助,在美国麻省理工大学电磁理论与应用中心(CETA)留学访问,在电磁材料设计和周期结构领域积累了丰富的研究经验。 2008年底回国后结合磁学、电磁学和材料学基础,主要研究方向为新型电磁波控制材料、结构设计与物理机制。承担参与包括国家自然基金、863子项目等多项国家、省部级科研项目,获国防科学技术进步一等奖。 教育部新世纪优秀人才、IEEE会员、材料研究学会(MRS)新加坡分会会员,教育部创新团队成员。 在《Applied Physics Letters》、《Optics Letters》、《Optics Express》、《Progress In Electromagnetics Research》、《Journal of Applied Physics》等刊物上发表SCI论文数十篇,引用百余次,为《Journal of Applied Physics》等国际期刊审稿人,多次参加IntermagProgress in Electromagnetic Research等国际国内会议并做特邀报告。电话:028-83201893,欢迎具有材料、磁性物理、电磁学基础的同学报考!

    电子邮件:  phzhou@uestc.edu.cn 

     

    学术经历:  1999.9-2003.6 电子科技大学 本科;2003.9-2009.12 电子科技大学 硕博连读;2007.11-2008.11 美国麻省理工大学 访问 


    科研项目:  低维磁性材料及动态磁化理论: 新型低维纳米磁性薄膜及结构制备、纳米磁体动态磁化机理及模型计算、复合磁性材料理论及电磁应用设计 ;红外微纳超结构及热辐射控制技术: 基于SPPs的红外微纳超结构设计及制备技术、亚波长金属周期结构电磁仿真及热辐射计算; 新型电磁超材料: 电磁超材料吸波设计及应用技术、电磁结构耦合特性及非线性研究。 

     

    发表文章:   近五年文章: [1] N. Zhang, P. H. Zhou*, D. M. Cheng, X. L. Weng, J. L. Xie, and L. J. Deng, Dual-band absorption of mid-infrared metamaterial absorber based on distinct dielectric spacing layers, Opt. Lett., Vol. 38, pp. 1125-1127, 2013 [2] G. R. Zhang, P. H. Zhou*, H. B. Zhang, L. B. Zhang, J. L. Xie, and L. J. Deng, Analysis and design of triple-band high-impedance surface absorber with periodic diversified impedance, J. Appl. Phys., Vol. 114, pp. 164103, 2013 [3] H. B. Zhang*, P. H. Zhou, H. P. Lu, Y. Q. Xu, D. F. Liang, and L. J. Deng, Resistance selection of high impedance surface absorbers for perfect and broadband absorption, IEEE Trans. Antennas Propag., Vol. 61, pp. 976-979, 2013 [4] N. Zhang, P. H. Zhou*, J. L. Xie, and L. J. Deng, Comparisons of two subwavelength aperture arrays with different lattice structure for light transmission, Optik, Vol. 124, pp. 2401-2405, 2013 [5] D. M. Cheng, J. L. Xie, P. H. Zhou, H. B. Zhang, N. Zhang, and L. J. Deng*, Numerical study of a new negative index material in mid-infrared spectrum, Opt. Express, Vol. 20, No. 23, pp. 25744-25751, 2012 [6] H. B. Zhang, P. H. Zhou, H. P. Lu, Y. Q. Xu, J. L. Xie and L. J. Deng. Soft magnetic film based metamaterial absorber. Electronics Letters, 2012, 48:435 [7] H. B. Zhang, P. H. Zhou, L. W. Deng, J. L. Xie, D. F. Liang and L. J. Deng. Frequency-dispersive resistance of high impedance surface absorber with trapezoid-coupling pattern. J. Appl. Phys., 2012, 112:014106 [8] P. H. Zhou*, L. R. Huang, J. L. Xie, D. F. Liang, H. P. Lu, and L. J. Deng, A study on the effective permittivity of carbon/PI honeycomb composites for radar absorbing design, IEEE Trans. Antenna Propag., Vol. 60, No. 6, pp. 3679-3683, 2012 [9] P. H. Zhou, T. Liu, J. L. Xie and L. J. Deng. Damping effect on resonance bounds of nanostructure ferromagnets and composites. J. Appl. Phys., 2012, 111:113912 [10] T. Liu, P. H. Zhou, D. F. Liang, J. L. Xie, L. J. Deng. Multi-resonances behavior of Ni nanobelt/paraffin composites at microwave frequencies. Journal of Alloys and Compounds. 2012, 524:25 [11] T. Liu, P. H. Zhou, D. F. Liang and L. J. Deng. Electromagnetic absorption properties of flowerlike cobalt composites at microwave frequencies. Chinese Physics B, 2012, 21(5): 50302-050302 [12] Y. Q. Xu*, P. H. Zhou, H. B. Zhang, L. Chen, and L. J. Deng, A wide-angle planar metamaterial absorber based on split ring resonator coupling, J. Appl. Phys., Vol. 110, pp. 044102, 2011 [13] H. Y. Chen*, L. J. Deng, P. H. Zhou, and J. L. Xie, Tapered impedance loading for suppression of edge scattering, IET Microwave Antenna & Propag., Vol. 5, No. 14, pp. 1744-1749, 2011 [14] H. Y. Chen*, L. J. Deng, and P. H. Zhou, Suppression of surface wave from finite conducting surfaces with impedance loading at margins, J. Electromag. Waves Appl., Vol. 24, No. 14/15, pp. 1977-1989, 2010 [15] P. H. Zhou*, L. Zhang, and L. J. Deng, Spin wave mode transition induced by surface anisotropy and characteristic length in magnetic nanoparticles, Appl. Phys. Lett., Vol. 96, pp. 112510, 2010 [16] P. H. Zhou, J. L. Xie, D. F. Liang, L. J. Deng. The co-effect of induced and structural anisotropies on nanocrystalline alloys. J. Magn. Magn. Mater., 2010, 322:3290-3292 [17] P. H. Zhou, Y. Q. Liu, L. J. Xie. Effect of 3d transition metal substitution on microstructure and microwave absorption properties of FeSiB nanocrystalline flakes. J. Magn. Magn. Mater., 2010, 322:794-798 [18] P. H. Zhou, L. J. Deng. Bounds on the dynamic magnetic properties of multiresonant nanostructure composites in exchange resonance model. J. Appl. Phys., 2009, 105:07A509 [19] P. H. Zhou, L. J. Deng. Multi-resonance mechanism study for nanocrystalline iron/paraffin composites based on exchange energy and bounds in gigahertz. IEEE Trans. Magn., 2009, 45:663-669 [20] P. H. Zhou, L. J. Deng, B.-I. Wu, J. A. Kong. Influence of scatterers geometry on power-law formula in random mixing composites. PIER, 2008, 85:69-82 [21] P. H. Zhou, L. J. Deng, J. L. Xie, D. F. Liang. Effects of particle morphology and crystal structure on the microwave properties of flake-like nanocrystalline Fe3Co2 particles. J. Alloys Compd., 2008, 448:303-307 [22] P. H. Zhou, J. L. Xie, Y. Q. Liu, L. J. Deng. Composition dependence of microstructure, magnetic and microwave properties in ball-milled FeSiB nanocrystalline flakes. J. Magn. Magn. Mater., 2008, 320:3390-3393