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赵前程

发布时间:2022-09-26 阅读量:

教育经历

 

时间

学 校

学位/专业

2008-2012

武汉理工大学

机械工程系 工学学士

2012-2014

武汉理工大学

光纤传感中心 硕士学位

2014-2016

英国伯明翰大学

机械工程系    硕士学位

2015-2019

澳大利亚新南威尔士大学

    电气工程及通信  博士学位

 

 

工作经历

 

时间

工作单位

职位

2019-2019

澳大利亚新南威尔士大学

博士后研究员

2019-2020

香港应用科技研究院

高级工程师

2020-2022

香港理工大学

博士后研究员

2022-至今

            bat365

副教授

 

研究方向

1)有源掺杂光纤的制备与宽带光纤器件设计(放大器,激光器,超荧光光源)

2)光纤传感(智慧光纤生命体征传感,物理量传感,光纤光栅传感)

3)功能光纤设计(超表面光纤,特种微结构光纤等)

 

研究成果

主要从事多年来一直致力于特种光纤制备与器件、光纤传感、功能光纤、光全息技术等方面的研究工作,并取得了一系列技术创新与理论研究成果。近6年内,发表学术论文共计30余篇,其中以第一作者发表的SCI收录15, 通信作者1,包括光纤技术、经典光学、纳米技术、应用物理等领域权威期刊ACS NANOOptics Letters 6篇)、Optics ExpressOptics Materials Express Applied Physics LettersNanomaterials等,多次参加国际光学顶级会议(包括多次在OFCCLEO等光纤技术顶级会议作口头报告)。以共同作者身份编写的英文著作2部《measurement of active fibers》,发表于国际认可出版社SpringerIOP Publishing group,发表以来至今下载次数已逾2万次。以第一申请人申请获批美国专利1项。作为主要成员参与国家自然基金项目3项,省部级项目2项,国际项目3项。并担任第26届香港光电与通信大会(OECC)技术项目委员会分会主席,以及经典光学物理权威期刊Journal of Lightwave Technology, Optics Letters, Optics Express等杂志审稿人.

相关的主要学术成果为:(1)首次提出并制备了铋//镱共掺石英光纤,单泵浦条件下获得0.9-1.7μm超宽带荧光光源;(2)提出并通过一系列后处理工艺,首次获得了铋铝共掺发光中心的发光物理机制,并获得铋铒掺杂光纤最优工作条件(温度,泵浦功率,浓度等);(3)首次提出并制备缠绕式布局和夹层式的多模光纤微弯生命体征传感床垫,可无接触式获得生命体征信号(呼吸,心跳等)(4)首次提出并设计了基于相位调控(纳米柱阵列)的近红外光子晶体光纤聚焦超表面透镜,实现了0.8-1.55μm波段的均匀、高效且远场(~300 μm)的聚焦。

 

代表论文

 

[1] Qiancheng Zhao, Weihao, Yuan, Jiaqi Qu, Cheng Zhi, Gang-Ding Peng and Changyuan Yu*. Optical Fiber-Integrated Metasurfaces: An Emerging Platform for Multiple Optical Applications [J]. Nanomaterials, 2022, 12(5): 793.

[2] Weihao Yuan, Qiancheng Zhao*, Linduo Li, Yu Wang and Changyuan Yu. Simultaneous measurement of temperature and curvature using ring-core fiber-based Mach-Zehnder interferometer [J]. Optics Express, 2021, 29(12):17915-17925.

[3] Qiancheng Zhao, Jiaqi Qu, Gang-Ding Peng and Changyuan Yu*. Endless Single-Mode Photonics Crystal Fiber Metalens for Broadband and Efficient Focusing in Near-Infrared Range [J]. Micromachines, 2021, 12(2):219-230.

[4] Qiancheng Zhao, Qun Hao*, Yanhua Luo, and Gang-Ding Peng. Photo-induced bleaching and thermally stimulated recovery of BAC-P in Bi-doped phosphosilicate fibers [J]. Optics Letters, 2020, 45(20):1150-1153.

[5] Qiancheng Zhao, Qun Hao*, Yanhua Luo, and Gang-Ding Peng. Thermal-induced luminescence enhancement of BAC-P in bismuth-doped phosphogerma4nosilicate fibers [J]. Optics Letters, 2020, 45(5):1152-1155.

[6] Qiancheng Zhao, Qun Hao*, Changyuan Yu, Fengze Tan, and Gang-Ding Peng. Influence of liquid nitrogen cooling on the spectral performance of BAC-P in bismuth-doped phosphosilicate fibers under liquid nitrogen temperature [J]. Optical Materials Express, 2020, 10(12):17889-17898.

[7] Qiancheng Zhao*, Yanhua Luo, Qun Hao and Gang-Ding Peng. Effect of thermal treatment parameters on the spectral characteristics of BAC-Al in bismuth/erbium codoped aluminosilicate fibers [J]. Optics Letters. 2019, 44(18):4594-4597.

[8] Qiancheng Zhao*, Yanhua Luo, Yutang Dai, and Gang-Ding Peng. Effect of pump wavelength and temperature on the spectral performance of BAC-Al in bismuth-doped aluminosilicate fibers [J]. Optics Letters, 2019, 44(3): 634-637.

[9] Qiancheng Zhao*, Jianzhong Zhang, Dan Sporea, Yanhua Luo, Jianxiang Wen, and Gang-Ding Peng. Gamma radiation and thermal-induced effects on the spectral performance of BACs in Bi/Er codoped aluminosilicate fibers [J]. Optics Express, 2019, 27(7):9955-9964.

[10] Qiancheng Zhao*, Yanhua Luo, Qun Hao and Gang-Ding Peng. Electron beam irradiation and thermal-induced effects on the spectral properties of BAC-Al in Bi/Er codoped aluminosilicate fibers [J]. Optical Materials Express, 2019, 9(11): 4287-4294.

[11] Qiancheng Zhao*, Yanhua Luo, Yuan Tian, and Gang-Ding Peng. Pump wavelength dependence and thermal effect of photobleaching of BAC-Al in bismuth/erbium codoped aluminosilicate fibers [J]. Optics Letters, 2018, 43(19):4739-4742.

[12] Qiancheng Zhao*, Jianzhong Zhang, Yanhua Luo, Jianxiang Wen, and Gang-Ding Peng. Energy transfer enhanced near-infrared spectral performance in bismuth/erbium codoped aluminosilicate fibers for broadband application [J]. Optics Express, 2018, 26(14):17889-17898.

[13] Qiancheng Zhao, Ali K Yetisen, Aydin Sabouri, Seok Hyun Yun, and Haider Butt. Printable Nanophotonic Devices via Holographic Laser Ablation [J]. ACS NANO, 2015, 9(9): 9062-9069.

[14] Qiancheng Zhao, Ali K Yetisen, Carl J Anthony, William R Fowler, Seok Hyun Yun, and Haider Butt*. Printable ink hologram [J]. Applied Physics Letters, 2015, 107(4): 041115.

[15] Qiancheng Zhao*, Yutang Dai, Tao Li, Bin Liu, Minghong Yang, and Guanglin Yin. Femtosecond laser ablation of microstructures in fiber and application in magnetic field sensing [J]. Optics Letters, 2014, 39(7):1905-1908.

 

英文专著/专利

[1] Gui Xiao, Ghazal Fallah Tafti, Amirhassan Zareanborji, Anahita Ghaznavi, Qiancheng Zhao, Measurement of Active Optical Fibers[M] In: Peng GD*. Ed. Handbook of Optical Fibers. Springer, Singapore, 2019.

[2] Yanhua Luo, * Desheng Fan, Mingjie Ding, Qiancheng Zhao, Binbin Yan, Jianxiang Wen, Gang-Ding Peng. The ionizing radiation effect of erbium, ytterbium, or bismuth doped/co-doped optical fibres. Optical Fiber Technology and Applications[M], IOP Publishing 2021: 5-1

[3] Qiancheng Zhao, Jacko LEUNG, Sam Kwok, Microbending Fiber-optic Sensor for Vital Sign Monitoring and Methods October, 2020, filed number: 17/083478.

 

联系方式

Email: qianchengzhao@cqu.edu.cn

地址:bat365在线登录网站A区主教学楼

诚挚欢迎对有源掺杂光纤器件,智能光纤传感,功能光纤有兴趣的本科生、硕士生、博士生联系和加入。