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谢振威
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谢振威

Xie Zhenwei  (谢振威)

Mobile:+86 15910648614

E-mail: ayst3_1415926@sina.com

            ayst31415926@szu.edu.cn


受教育经历:

200509月—200907月,哈尔滨工业大学 光信息科学与技术专业 学士

200909月—201107月,哈尔滨工业大学 理学院 光学 硕士

201109月—201507月,哈尔滨工业大学 理学院 物理学 博士

研究经历:

2015/09 –至今   深圳大学光电工程学院,博士后,合作导师:袁小聪

主要学术业绩:

谢振威,男,博士。主要从事波前调制技术、太赫兹波前调制、超表面器件、微纳光学、微纳加工、光学信息处理等领域的应用技术研究。在波前调制技术、超表面器件设计、三维微纳结构加工等方向做出有创新意义的科研成果。在Advanced Optical MaterialsScientific ReportsNanoscaleLaser & Photonics ReviewsOptics LettersOptics Express等光学类刊物上期刊论文20余篇,在IOTICOPEN等国际会议上发表会议论文2篇。目前所取得主要研究成果的重要性如下:1)在光纤的端面设计并制作了一种仙人掌状的三维拉曼增强结构,实现了远程拉曼信号的测量。所提出光纤拉曼雷达采用光纤作为基底,可实现远程、实时拉曼光谱的传感检测。该光纤拉曼雷达传感器件具有体积小、携带方便、抗干扰能力强等诸多优势,可适用于检测空间狭小,被检测物难以接近、检测环境有毒有害等极端情况下的传感检测。相关成果以封面文章的形式发表于Advanced Optical MaterialsJCR一区,IF5.359);2)提出了一种用光生载流子来动态调制太赫兹波前的方法。所提出的太赫兹调制器具有加工简单、高分辨率和宽带的特性。相对于其他太赫兹调制器,本方法具有以下创新性和优势:本方法无需复杂的加工工艺,不需要加工金属结构。本方法的空间分辨率可以达到太赫兹波长的十分之一甚至百分之一量级。本调制器是通过光来控制的,抗干扰能力强。具有宽谱适用范围,而且具有较高的调制速率。通过光控的计算全息技术可以实现对太赫兹强度和相位的同时进行控制,这种太赫兹调制器有望被应用于将来的太赫兹成像和通信系统中。相关成果发表于Scientific ReportsJCR二区,IF5.228);3)提出了一种可以生成太赫兹矢量光束的方法,这种方法将亚波长的金属光栅与动态光控的太赫兹全息技术相结合。用亚波长金属光栅控制偏振态,而用光生载流子的计算全息图来控制复振幅,从而达到控制矢量太赫兹波前的目的,本方法具有加工简单、宽带适用、以及动态可调等方面的优势。本方法或可用于将来的太赫兹传感、成像和通信系统中。相关成果发表于Optics LettersJCR二区,IF3.040);4)首次提出了一种利用聚合物光栅检测矢量光束拓扑荷的方法。相关成果发表于IEEE Photonic Technology Letters.

近五年代表性论文:

[1].   Z. Xie, T. Lei, X. Weng, L. Du, S. Gao, Y. Yuan, S. Feng, Y. Zhang, and X. Yuan, A Miniaturized Polymer Grating for Topological Order Detection of Cylindrical Vector Beams, IEEE Photonics Technology Letters, 28(24), pp. 2799-2802, 2016.

[2].   Z. Xie, J. He, X. Wang, S. Feng, and Y. Zhang, Generation of terahertz vector beams with a concentric ring metal grating and photo-generated carriers, Optics letters, 40(3), pp. 359-362, 2015.

[3].   Z. Xie, S. Feng, P. Wang, L. Zhang, X. Ren, L. Cui, T. Zhai, J. Chen, Y. Wang, and X. Wang, Demonstration of a 3D Radar‐Like SERS Sensor Micro‐and Nanofabricated on an Optical Fiber, Advanced Optical Materials, 3(9), pp. 1232-1239, 2015.

[4].   Z. Xie, J. L. Zang, and Y. Zhang, Accelerated algorithm for three-dimensional computer generated hologram based on the ray-tracing method, Journal of Modern Optics, 60(10), pp. 797-802, 2013.

[5].   Z. Xie, X. Wang, J. Ye, S. Feng, W. Sun, T. Akalin, and Y. Zhang, Spatial terahertz modulator, Scientific Reports, 3, pp. 3347, 2013.

[6].   Z. Xie, J. Zang, and Y. Zhang, "Image encryption under spatially incoherent illumination," in International Conference on Optics in Precision Engineering and Nanotechnology (icOPEN2013)(International Society for Optics and Photonics2013), pp. 876920-876920-876928.

[7].   Z. Xie, X. Wang, and Y. Zhang, "Active terahertz holography," in International Conference on Optical Instruments and Technology (OIT2013) (International Society for Optics and Photonics2013), pp. 90470B-90470B-90476.

[8].   J. Wu, Z. Xie, Z. Liu, W. Liu, Y. Zhang, and S. Liu, Multiple-image encryption based on computational ghost imaging, Optics Communications, 359, pp. 38-43, 2016.

[9].   H. Wang, Z. W. Xie, M. L. Zhang, H. L. Cui, J. S. He, S. F. Feng, X. K. Wang, W. F. Sun, J. S. Ye, P. Han, and Y. Zhang, [INVITED] A miniaturized optical fiber microphone with concentric nanorings grating and microsprings structured diaphragm, Optics and Laser Technology, 78, pp. 110-115, 2016.

[10]. H. Wang, Z. Xie, S. Feng, and Y. Zhang, "3D Micro-and nano sensing devices creation on the facets of optical fibers via two-photon lithography," in Progress in Electromagnetic Research Symposium (PIERS)(IEEE2016), pp. 3348-3348.

[11]. J. He, Z. Xie, W. Sun, X. Wang, Y. Ji, S. Wang, Y. Lin, and Y. Zhang, Terahertz tunable metasurface lens based on vanadium dioxide phase transition, Plasmonics, 11(5), pp. 1285-1290, 2016.

[12]. J. Han, Z. Xie, S. Feng, and Y. Zhang, "Seven-core fiber SPR sensor," in Progress in Electromagnetic Research Symposium (PIERS)(IEEE2016), pp. 596-596.

[13]. B. Wang, Z. Xie, S. Feng, B. Zhang, and Y. Zhang, Ultrahigh Q-factor and figure of merit Fano metamaterial based on dark ring magnetic mode, Optics Communications, 335, pp. 60-64, 2015.

[14]. W. Liu, Z. Xie, Z. Liu, Y. Zhang, and S. Liu, Multiple-image encryption based on optical asymmetric key cryptosystem, Optics Communications, 335, pp. 205-211, 2015.

[15]. J. He, Z. Xie, S. Wang, X. Wang, Q. Kan, and Y. Zhang, Terahertz polarization modulator based on metasurface, Journal of Optics, 17(10), pp. 105107, 2015.

[16]. X. Wang, Z. Xie, W. Sun, and Y. Zhang, "Optical steerable terahertz zone plate," in Infrared, Millimeter, and Terahertz waves (IRMMW-THz), 2014 39th International Conference on(IEEE2014), pp. 1-2.

[17]. J. Zang, Z. Xie, and Y. Zhang, Optical image encryption with spatially incoherent illumination, Optics letters, 38(8), pp. 1289-1291, 2013.

[18]. X. Wang, Z. Xie, W. Sun, S. Feng, Y. Cui, J. Ye, and Y. Zhang, Focusing and imaging of a virtual all-optical tunable terahertz Fresnel zone plate, Optics letters, 38(22), pp. 4731-4734, 2013.

[19]. Y. Yuan, T. Lei, Z. Li, Y. Li, S. Gao, Z. Xie, and X. Yuan, Beam wander relieved orbital angular momentum communication in turbulent atmosphere using Bessel beams, Scientific Reports, 7, 2017.

[20]. L. Zhang, X. Dou, C. Min, Y. Zhang, L. Du, Z. Xie, J. Shen, Y. Zeng, and X. Yuan, In-plane trapping and manipulation of ZnO nanowires by a hybrid plasmonic field, Nanoscale, 8(18), pp. 9756-9763, 2016.

[21]. B. Wang, B. Quan, J. He, Z. Xie, X. Wang, J. Li, Q. Kan, and Y. Zhang, Wavelength de-multiplexing metasurface hologram, Scientific Reports, 6, 2016.

[22]. C. Min, J. Liu, T. Lei, G. Si, Z. Xie, J. Lin, L. Du, and X. Yuan, Plasmonic nano‐slits assisted polarization selective detour phase meta‐hologram, Laser & Photonics Reviews, 10(6), pp. 978-985, 2016.

[23]. J. He, S. Wang, Z. Xie, J. Ye, X. Wang, Q. Kan, and Y. Zhang, Abruptly autofocusing terahertz waves with meta-hologram, Optics Letters, 41(12), pp. 2787-2790, 2016.

[24]. S. Gao, T. Lei, Y. Li, Y. Yuan, Z. Xie, Z. Li, and X. Yuan, OAM-labeled free-space optical flow routing, Opt. Express, 24(19), pp. 21642-21651, 2016.

[25]. Y. Zhang, X. Wang, J. He, and Z. Xie, "Active modulation of terahertz wavefront," in Infrared, Millimeter, and Terahertz waves (IRMMW-THz), 2015 40th International Conference on(IEEE2015), pp. 1-1.

[26]. W. Liu, Y. Zhang, Z. Xie, Z. Liu, and S. Liu, Secure optical verification using dual phase-only correlation, Journal of Optics, 17(2), pp. 025703, 2015.

[27]. X. Wang, S. Wang, Z. Xie, W. Sun, S. Feng, Y. Cui, J. Ye, and Y. Zhang, Full vector measurements of converging terahertz beams with linear, circular, and cylindrical vortex polarization, Opt. Express, 22(20), pp. 24622-24634, 2014.

[28]. D. Hu, G. Moreno, X. Wang, J. He, A. Chahadih, Z. Xie, B. Wang, T. Akalin, and Y. Zhang, Dispersion characteristic of ultrathin terahertz planar lenses based on metasurface, Optics Communications, 322, pp. 164-168, 2014.

[29]. L. Deng, T. Henning, P. J. Klar, S. Feng, Z. Xie, X. Wang, W. Sun, J. Ye, P. Han, and Y. Zhang, Optimization of the Rayleigh anomaly of metallic gratings for terahertz sensor applications, Journal of Optics, 16(9), pp. 094015, 2014.