| 周俊泽 副研究员 junzezhou@fyust.edu.cn 研究领域:拟搭建纳米压印探针实验室,开展纳米光子学相关研究与合作 |
个人简介
周俊泽博士,先后在欧洲和美国学习与科研,研究方向涉及近场光学探针、纳米压印技术、以及纳米光电子材料。在博士后期间,参与美国国家实验室科研仪器研发。研究成果发表在Nature communication、Nano Letters、Review ofScientific Instruments、Optics Express 等期刊,并多次受邀为知名期刊审稿。曾获国家奖学金和留学基金委公派留学奖学金等多项奖励。
教育背景
2013 年哈尔滨工业大学 材料物理(学士)
2019 年法国特鲁瓦科技大学 纳米光子学(硕博)
工作履历
2019-2024,美国劳伦斯伯克利国家实验室 博士后
2024-至今,福耀科技大学,新材料与新能源学院,副研究员
邀请报告
1. Junze Zhou, “Nanoimprinted pyramid scanning probe for nanoscale optical mapping”, FACSS SCIX2023, Reno, Nevada.
2. Junze Zhou, “Giant defect emission enhancement of ZnO through desulfurization process”. SPIE Optics and Photonics, 2018, San Diego, California.
学术成果
1. J. Zhou*, A. Gonçalves, F. Riminucci, S. Dhuey, E. Barnard, A. Schwartzberg, F. J. Garcia de Abajo*, A. Weber-Bargioni*, “Probing plexciton emission from 2D materials on gold nanotrenches”. Nature Communication, 15, 9583 (2024).
2. J. Zhou*, J. Thomas, E. Barre, E. Barnard, A. Raja, S. Cabrini, K. Munechika, A. Schwartzberg*, A. Weber-Bargioni*, ''Near-field Coupling with a Nanoimprinted Probe for Dark Exciton Nanoimaging in Monolayer WSe2'', Nano Letters, 23, 4901-4907 (2023).
3. J. Zhou*, E. S. Barnard, S. Cabrini, K. Munechika, A. Weber-Bargioni, A. Schwartzberg, ''Integrating Collapsible Plasmonic Gaps on Near-field Probes for Polarization-resolved mapping of Plasmon-enhanced Emission in 2D material'', Optics Express 31, 20440-20448 (2023).
4. J. Zhou*, A. Gashi, F. Riminucci, B. Chang, E. S. Barnard, S. Cabrini, A. Weber-Bargioni, A. Schwartzberg*, K. Munechika*, ''Sharp, high numerical aperture (NA), nanoimprinted bare pyramid probe for optical mapping'', Review of Scientific Instruments 94, 033902 (2023).
5. J. Zhou*, K. Nomenyo, C. C. Cesar, A. Lusson, A. Schwartzberg, C. Yen, W. Woon and G. Lérondel*, “Giant defect emission enhancement from ZnO nanorods through desulfurization process”. Scientific Reports 10, 4237 (2020).
6. J. Zhou*, L.O. Le Cunff, K. Nomenyo, A. Vial, T. Pauporté, G. Lérondel*, ''Phenomenological modeling of light transmission through nanowires arrays'', Thin Solid Films 675, 43-49 (2019).
7. Y. Huang, J. Zhou, A. Gokarna, G. Lérondel*, ‘‘Facile, wafer-scale compatible growth of ZnO nanowires via chemical bath deposition: assessment of zinc ion contribution and other limiting factors’’. Nanoscale Advances 2 (11), 5288-5295 (2020). (Co-first authors)
