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| Jiang Xiaoshun Professor Email: jxs@nju.edu.cn Personal homepage: http://optics.nju.edu.cn/memberdetail.aspx?i=5 Lab homepage: http://optics.nju.edu.cn |
| Research field
Courses
Profile Professor Jiang participated in the joint PhD program in California Institute of Technology from 2007 to 2009 and received his doctorate from Zhejiang University in 2010. His research interests lie in the preparation of chip-based high Q-factor optical microresonator and its application in integrated photonics devices, photomechanics, parity-time symmetrical photonics, and nonlinear optics. He was awarded the first prize of the Natural Science Awards of Zhejiang Province (ranking the third) in 2014 and Science Fund for Distinguished Young Scholars of Jiangsu Province in 2015. He was also selected into Tier-B Peak Climbers Scholar Support Program of Nanjing University. Jiang has published over 30 papers on international journals such as Nature Photonics, Nature Communications, Physical Review Letters, Applied Physics Letters, Optics Express and Optics Letters. According to Google Scholar, his articles have been cited for over 1,300 times. Representative publications: (Note: * refers to corresponding author.) [1] Hua, Shiyue, Wen, Jianming, Jiang, Xiaoshun,* Hua, Qian, Jiang, Liang, & Xiao, Min. (2016). Demonstration of a chip-based optical isolator with parametric amplification. Nature Communications, 7, 13657. [2] Chang, Long, Jiang, Xiaoshun,* Hua, Shiyue, Yang, Chao, Wen, Jianming, Jiang, Liang, Li, Guanyu, Wang, Guanzhong, & Xiao, Min. (2014). Parity-time symmetry and variable optical isolation in active-passive-coupled microresonators. Nature Photonics, 8(7), 524. [3] Yang, Chao, Jiang, Xiaoshun,* Hua, Qian, Hua, Shiyue, Chen, Yuan, Ma, Jiyang, & Xiao, Min. (2017). Realization of controllable photonic molecule based on three ultrahigh-Q microtoroid cavities. Laser & Photonics Reviews, 11(2), 1600178. (Front Cover) [4] Yang, Chao, Hu, Yong, Jiang, Xiaoshun,* & Xiao, Min. (2017). Analysis of a triple-cavity photonic molecule based on coupled-mode theory. Physical Review A, 95(3), 033847. [5] Wang, Guanzhong, Zhao, Mingming, Qin, Yingchun, Yin, Zhangqi, Jiang, Xiaoshun,* & Xiao, Min. (2017). Demonstration of an ultra-low-threshold phonon laser with coupled microtoroid resonators in vacuum. Photonics Research, 5(2), 73-76. (Cover) [6] Li, Guanyu, Jiang, Xiaoshun,* Hua, Shiyue, Qin, Yingchun, & Xiao, Min. (2016). Optomechanically tuned electromagnetically induced transparency-like effect in coupled optical microcavities. Applied Physics Letters, 109(26), 261106. [7] Jiang, Xiaoshun,* Yang, Chao, Wu, Hongya, Hua, Shiyue, Chang, Long, Ding, Yang, Hua, Qian, & Xiao, Min. (2016). On-chip optical nonreciprocity using an active microcavity. Scientific Reports, 6, 38972. [8] Li, Guanyu, Liu, Pei, Jiang, Xiaoshun,* Yang, Chao, Ma, Jiyang, Wu, Hongya, & Xiao, Min. (2015). High-Q silica microdisk optical resonators with large wedge angles on a silicon chip. Photonics Research, 3(5), 279-282. [9] Fan, Huibo, Jiang, Xiaoshun,* Ding, Yang, & Xiao, Min. (2015). Demonstration of ultralow-threshold 2 micrometer microlasers on chip. Science China Physics, Mechanics & Astronomy, 58(11), 114204. (Cover) [10] Zheng, Binbin, Zhao, Mingxiao, Guo, Qiangbing, Yu, Yongze, Lu, Shichao, Jiang, Xiaoshun,* & Zhou, Shifeng. (2015). A chip-based microcavity derived from multi-component tellurite glass. Journal of Materials Chemistry C, 3(20), 5141-5144. [11] Wang, Guanzhong, Zhao, Mingming, Ma, Jiyang, Li, Guanyu, Chen, Yuan, Jiang, Xiaoshun,* & Xiao, Min. (2015). Radiation-pressure-driven mechanical oscillations in silica microdisk resonators on chip. SCIENCE CHINA Physics, Mechanics & Astronomy, 58(5), 1-4. (Special Issue on Optomechanics) [12] Fan, Huibo, Hua, Shiyue, Jiang, Xiaoshun,* & Xiao, Min. (2013). Demonstration of an erbium-doped microsphere laser on a silicon chip. Laser Physics Letters, 10(10), 105809. [13] Wang, Guanzhong, Jiang, Xiaoshun,* Zhao, Mingxiao, Ma, Yaoguang, Fan, Huibo, Yang, Qing, Tong, Limin & Xiao, Min. (2012). Microlaser based on a hybrid structure of a semiconductor nanowire and a silica microdisk cavity. Optics Express, 20(28), 29472-29478. [14] Zheng, Can, Jiang, Xiaoshun,* Hua, Shiyue, Chang, Long, Li, Guanyu, Fan, Huibo, & Xiao, Min. (2012). Controllable optical analog to electromagnetically induced transparency in coupled high-Q microtoroid cavities. Optics Express, 20(16), 18319-18325. [15] Jiang, Xiaoshun, Lin, Qiang, Rosenberg, Jessie, Vahala, Kerry J., & Painter, Oskar. (2009). High-Q double-disk microcavities for cavity optomechanics. Optics Express, 17(23), 20911-20919. [16] Lin, Qiang, Rosenberg, Jessie, Jiang, Xiaoshun, Vahala, Kerry J., & Painter, Oskar. (2009). Mechanical oscillation and cooling actuated by the optical gradient force. Physical Review Letters, 103(10), 103601. [17] Jiang, Xiaoshun, Chen, Yuan, Vienne, Guillaume, & Tong, Limin. (2007). All-fiber add-drop filters based on microfiber knot resonators. Optics Letters, 32(12), 1710-1712. [18] Jiang, Xiaoshun, Song, Qinghai, Xu, Lei, Fu, Jian, & Tong, Limin. (2007). Microfiber knot dye laser based on the evanescent-wave-coupled gain. Applied Physics Letters, 90(23), 233501. [19] Jiang, Xiaoshun, Yang, Qing, Vienne, Guillaume, Li, Yuhang, Tong, Limin, Zhang, Junjie, & Hu, Lili. (2006). Demonstration of microfiber knot laser. Applied Physics Letters, 89(14), 143513. [20] Jiang, Xiaoshun, Tong, Limin, Vienne, Guillaume, Guo, Xin, Tsao, Albert, Yang, Qing, & Yang, Deren. (2006). Demonstration of optical microfiber knot resonators. Applied Physics Letters, 88(22), 223501.
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