谢微

      2007.09.—2012.07     复旦大学     物理系光学专业   硕士&博士

      2002.09.—2006.07     上海大学     物理系光电子专业      学士

2015.09.—至今     金沙   精密光谱实验室   紫江学者

2014.05.—2015.08  美国密西根州立大学大学          博士后

主要从事微纳光学和量子调控领域的实验研究工作，研究方向包括微纳光学结构集体量子行为及调控技术、超快光学编码和光子集成芯片、低维和表界面体系的光谱及超快时间动力学等。近年来以通讯作者/第一作者在 Phys. Rev. Lett..、 PNAS、  Nat. Commun、  Light Sci. Appl.、  Optica、  Laser Photonics Rev.  等国际一流学术刊物发表SCI论文40余篇。主持和参与多项国家自然科学基金和科技部科研项目。

从事微纳结构光学性质及光子集成芯片方向的实验研究工作

    利用微纳结构与低维材料获得新颖、可控的光学效应是当今物理研究和科技应用的热门领域之一。实验上我们利用微纳加工及微区自组装技术，制备高质量微结构样品和光电器件原型。结合已搭建的多维度光学探测平台(角度分辨荧光光谱、发光动力学测量、光斑形状调控-微区探测、低温-磁场-电场等外场环境辅助等)，研究半导体光学微腔和微纳周期结构中光-物质作用和宏观量子行为的相干调控；我们将量子调控与微纳光子学、量子光学与量子材料相融合，开拓基于相干操控的元激发粒子-微纳光子混合体系及相关量子器件的新方向，开发其在光电集成微芯片等方面的潜在应用。

方向1：微纳光学结构中的多体量子行为及调控技术

量子点超晶格中的腔增强超荧光效应：融合传统激光和超辐射效应，在微纳尺度首次实现腔增强超荧光集体辐射。将量子点团簇中激子系综的辐射速率提高三个数量级。[Nat. Commun., 11, 329 (2020).  https://www.nature.com/articles/s41467-019-14078-1.]

方向2：超快光信息编码和光子集成芯片

单个纳米球演示太赫兹高带宽光学编码：基于单个钙钛矿纳米球光学激射实现的多参量关联超快编码，可调带宽高达0.2 THz。将钙钛矿的应用领域从光学储能材料拓展到信息编码器件。

[Laser & Photonics Reviews, 1900398 (2020). https://doi.org/10.1002/lpor.201900398. 

  Light: Science & Applications, 10: 60 (2021). https://doi.org/10.1038/s41377-021-00508-7.]

方向3：半导体微纳结构多维光谱及超快时间动力学

半导体量子阱准费米面处的光-物质集体相干行为及其动力学演化：将半导体光学领域相干凝聚的存在范围首次拓展到电子-空穴等离子体相。揭示等离子体凝聚团间的关联机理，发展动态相位调控技术。

[Phys. Rev. Lett., 124, 157402 (2020). https://doi.org/10.1103/PhysRevLett.124.157402.

  Optica, vol.3, no.12, (2016). https://doi.org/10.1364/OPTICA.3.001477.]

学生招生及毕业去向    

    课题组常年招收多名硕士、博士、博士后，欢迎有志于微纳光物理探索和光子集成芯片开发的盟友们加入！

    本课题组在读博士生5 名、硕士生4 名。毕业博士生2名（就业于山西省中北大学大学、杭州市高研院）、硕士生4名（就业于金沙、西安第七中学、苏州教育文体委等单位）。

《半导体光谱和光学性质》、《量子测量原理与技术》、《物理实验（一）》、《力学》等

主持国家自然科学基金面上项目、国家自然科学基金青年项目。参与多项国家科技部科研项目。

2021年科研论文：

1. “Ultrastable low-cost colloidal quantum dot microlasers of operative temperature up to 450 K”, Hao Chang, Yichi Zhong, Hongxing Dong*, Zhenyu Wang, Wei Xie*, Anlian Pan, Long Zhang*, Light: Science & Applications, 10: 60 (2021). https://doi.org/10.1038/s41377-021-00508-7

2020年科研论文：

1. “Room-temperature Macroscopic Coherence of Two Electron-hole Plasmas in a Microcavity”, Qi Jie, Keye Zhang, Chih-Wei Lai, Feng-Kuo Hsu, Weiping Zhang*, Song Luo, Yi-Shan Lee, Sheng-Di Lin, Zhanghai Chen and Wei Xie*, Phys. Rev. Lett., 124, 157402 (2020). https://doi.org/10.1103/PhysRevLett.124.157402

2. “Cooperative excitonic quantum ensemble in perovskite-assembly superlattice microcavities”, Chun Zhou+, Yichi Zhong+, Hongxing Dong*, Weihao Zheng, Jiqing Tan, Qi Jie, Anlian Pan, Long Zhang* and Wei Xie*, Nat. Commun., 11, 329, (2020). https://www.nature.com/articles/s41467-019-14078-1

3. “All-Photonic Miniature Perovskite Encoder with a Terahertz Bandwidth”, Yichi Zhong; Bing Tang; Meng Fei; Qi Jie; Jiqing Tan; Qiangqiang Wang; Shuang Liang; Junjie Du; Long Zhang; Hongxing Dong* and Wei Xie*, Laser & Photonics Reviews, 1900398, (2020). https://doi.org/10.1002/lpor.201900398

4. “Linearly polarized lasing based on coupled perovskite microspheres”, Beier Zhou+, Yichi Zhong+, Mingming Jiang, Jianhao Zhang, Hongxing Dong*, Linqi Chen, Hao Wu, Wei Xie* and Long Zhang*, Nanoscale, 12, 5805 (2020). https://doi.org/10.1039/C9NR09259E

2019年科研论文：

1. “Highly linear polarized photoluminescence from a rippled WSe2 monolayer”, Bilin Li, Zhongqi Ren, Ni Zhong, and Wei Xie*, Optics Express, vol.27, no.9, (2019)

2018年及以前的科研论文：

1. “Multiple-pulse microcavity lasing from an optically induced confinement”,  Wei Xie, Feng-Kuo Hsu, Yi-Shan Lee, Sheng-Di Lin, ChihWei Lai*, Optica, vol.3, no.12, (2016)

2. “Weak lasing in one-dimensional polariton superlattices”, Long Zhang+, Wei Xie+, Xuechu Shen, Zhanghai Chen*, et al., Proceedings of the National Academy of Sciences (PNAS), vol.112, no.13, (2015) 

3. “Room-temperature polariton parametric scattering driven by a one-dimensional polariton condensate”, Wei Xie, Hongxing Dong, Xuechu Shen, Zhanghai Chen*, et al., Phys. Rev. Lett., 108, 166401 (2012)

4. “Exciton-polariton condensate induced by evaporative cooling in a three-dimensionally confined microcavity”, Jian Wang, Wei Xie*, Xuechu Shen, Zhanghai Chen*, et al., Phys. Rev. B, vol.91, 165423 (2015)

5. “Room-temperature polariton waveguide effect in a ZnO microwire”, Yanjing Ling, Wei Xie*, Zhanghai Chen*, et al., Appl. Phys. Express, 8 031102 (2015)

6. “Linearly Polarized Remote-Edge Luminescence in GaSe Nanoslabs”, Yanhao Tang, Wei Xie, John A. McGuire, and C. W. Lai *, Phys. Rev. Applied, 4, 034008 (2015)

7. “Ultrafast spin-polarized lasing in a highly photoexcited semiconductor microcavity at room temperature”, Feng-Kuo Hsu, Wei Xie, Yi-Shan Lee, Sheng-Di Lin, ChihWei Lai*., Phys. Rev. B, 91, 195312 (2015)

8. “Optical and spin polarization dynamics in GaSe nanoslabs”, Yanhao Tang, Wei Xie, Krishna C. Mandal, John A. McGuire, and C. W. Lai *, Phys. Rev. B, 91, 195429 (2015)

9. “Coherent scattering of exciton polaritons and acoustic phonons in a ZnO single crystal”, Wenhui Liu, Wei Xie, Xuechu Shen, Zhanghai Chen*, et al., Phys. Rev. B, 89, 201201(R) (2014)

10. “Transient dual-energy lasing in a semiconductor microcavity”, Feng-Kuo Hsu, Wei Xie, Yi-Shan Lee, Sheng-Di Lin, ChihWei Lai*, Sci. Rep. 5, 15347 (2015)

11. “Robust exciton-polariton effect in a ZnO whispering gallery microcavity at high temperature”, Saifeng Zhang, Wei Xie, Xuechu Shen, Zhanghai Chen*, et al., Appl. Phys. Lett., 100, 101912 (2012)

12. “Angle-Dependent Resonant Light Absorption of Polariton States in One-Dimensional ZnO Microcavities”, Wenhui Liu, Dan Xu, Wei Xie, Xuechu Shen, Zhanghai Chen*, et al., Appl. Phys. Express, 6, 091101 (2013)

13. “Strong bound exciton-photon coupling in ZnO whispering gallery microcavity”, Liaoxin Sun, Hongxin Dong, Wei Xie, Xuechu Shen, Zhanghai Chen*, et al., Optics Express, 21, 030227 (2013)

14. “Spin-Resolved Purcell Effect in a Quantum Dot Microcavity System”, Ren, QJ, Lu, J, Tan, HH, Wu, S, Sun, LX, Zhou, WH, Wei Xie, Zhanghai Chen*, et al., Nano Letters, 12, 3008083 (2012)

15. “Indium oxide octahedra optical microcavities”, Hongxin Dong, Liaoxin Sun, Wei Xie, Xuechu Shen, Zhanghai Chen*, et al., Appl. Phys. Lett., 97, 223114 (2010)

16. “Polariton lasing of quasi-whispering gallery modes in a ZnO microwire”, Duan, Qingqing; Xu, Dan; Liu, Wenhui; Lu, Jian; Zhang, Long; Wang, Jian; Wang, Yinglei; Gu, Jie; Hu, Tao; Xie, Wei; Shen, Xuechu; Chen, Zhanghai, Appl. Phys. Lett., 103, 2, (2013)

17. “One-dimensional ZnO exciton polaritons with negligible thermal broadening at room temperature”, Trichet, A.; Sun, L.; Pavlovic, G.; Gippius, N. A.; Malpuech, G.; Xie, W.; Chen, Z.; Richard, M.; Dang, Le Si, Phys. Rev. B, 83, 4 (2011)

18. “Single-crystalline polyhedral In2O3 vertical Fabry-Perot resonators”, Dong, Hongxing; Sun, Shulin; Sun, Liaoxin; Xie, Wei; Zhou, Lei; Shen, Xuechu; Chen, Zhanghai, Appl. Phys. Lett., 98, 1, (2011)

19. “Facile Synthesis and Ultraviolet Lasing Properties a ZnO Microtubes”, Dong, Hongxing; Sun, Liaoxin; Xie, Wei; Zhou, Weihang; Shen, Xuechu; Chen, Zhanghai*, J. Phys. Chem. C, 114, 41: 17369~17373, (2010)

20. “Quasi-whispering gallery modes of exciton-polaritons in a ZnO microrod”, Liaoxin Sun, Hongxin Dong, Wei Xie, Xuechu Shen, Zhanghai Chen*, et al., Optics Express, 18, 015371 (2010)