教育经历:
2006年9月——2011年6月,吉林大学美高梅mgm7991,博士
2002年9月——2006年6月,吉林大学美高梅mgm7991,学士
工作经历:
2014年11月至今, 美高梅mgm7991,副研究员
2014年1月——2014年10月,中科院西安光机所,副研究员
2011年7月——2013年12月,中科院西安光机所,助理研究员
2011年7月——2014年10月,中科院西安光机所,博士后
研究方向:
1. 光与原子耦合体系的量子相干效应
2. 量子成像和关联成像
主持项目:
1. 基于驻波场和原子耦合体系的量子相位门和量子纠缠,中国博士后科学基金特别资助
2. 基于驻波场诱导量子相干效应的弱光非线性和原子光刻,国家自然科学基金青年项目
3. 量子××××技术,国家863计划项目
4. 驻波场与原子耦合体系的量子相干效应研究,中国博士后科学基金
5. 量子××××技术,国家863计划项目
6. 消除大气湍流影响的双光子关联成像研究,国家重点实验室自主课题
7. 双环形腔与相干原子耦合体系的光学双稳和非线性动力学研究,陕西省自然科学基础研究计划
科研论文:
1. Y. Y. Chen, Y. N. Li, and R. G. Wan*, “Double-cavity optical bistability and all-optical switching in four-level N-type atomic system,” Journal of the Optical Society of America B 35, 1240 (2018).
2. Y. Y. Chen, Z. Z. Liu, and R. G. Wan*, “Electromagnetically induced two-dimensional grating assisted by incoherent pump,” Physics Letters A 381, 1362 (2017).
[3] 3. Y. Y. Chen, Z. Z. Liu, and R. G. Wan*, “Beam splitter and router via an incoherent pump-assisted electromagnetically induced blazed grating,” Applied Optics 56, 5736 (2017).
[4] 4. Y. Y. Chen, Z. Z. Liu, and R. G. Wan*, “Electromagnetically induced 2D grating via refractive index enhancement in a far-off resonant system,” Laser Physics Letters 14, 075202 (2017).
[5] 5. Z. Z. Liu, Y. Y. Chen, J. Y. Yuan, and R. G. Wan*, “Two-dimensional electromagnetically induced grating via nonlinear modulation in a five-level atomic system,” Optics Communications 402, 545 (2017).
[6] 6. J. Y. Yuan, Y. Y. Chen, Z. Z. Liu, and R. G. Wan*, “Correlated imaging with partially coherent light for remote sensing,” Journal of Modern Optics 64, 1708 (2017).
[7] 7. Y. Y. Chen, Z. Z. Liu, and R. G. Wan*, Electromagnetically Induced Grating Without Absorption Using Incoherent Pump,Int. J. Theor. Phys., 2017, 56: 3117.
[8] 8. Z. Z. Liu, Y. Y. Chen, J. Y. Yuan, and R. G. Wan*, Coherently induced grating in refractive index enhanced medium, Chinese Physics B, 2017, 26: 124209.
[9] 9. Y. Y. Chen, Z. Z. Liu, and R. G. Wan*, “Two-dimensional electromagnetically induced grating in coherent atomic medium,” EPL 116, 64006 (2016).
10. L. Jiang, R. G. Wan*, and Z. H. Yao, “Spontaneous emission from a microwave-driven four-level atom in an anisotropic photonic crystal,” Chinese Physics B 25, 104204 (2016).
11. R. G. Wan*, T. Y. Zhang, and J. Kou, “Two-dimensional sub-half-wavelength atom localization via phase control of absorption and gain,” Physical Review A 87, 043816 (2013).
12. Y. P. Yao, T. Y. Zhang, J. Kou, and R. G. Wan*, “Photonic bandgap via nonlinear modulation assisted by spontaneously generated coherence,” Physics Letters A 377, 1416 (2013).
13. R. G. Wan*, and T. Y. Zhang, “Two-dimensional sub-half-wavelength atom localization via controlled spontaneous emission,” Optics Express 19, 25823 (2012).
14. R. G. Wan, J. Kou, L. Jiang, Y. Jiang, and J. Y. Gao*, “Electromagnetically induced grating via enhanced nonlinear modulation by spontaneously generated coherence,” Physical Review A 83, 033824 (2011).
15. R. G. Wan, J. Kou, L. Jiang, Y. Jiang, and J. Y. Gao*, “Magneto-optical switching and routing via coherently induced photonic band gaps in a driven Fe=0-Fg=1 transition,” Journal of Physics B 44, 065502 (2011).
16. R. G. Wan, J. Kou, L. Jiang, Y. Jiang, and J. Y. Gao*, “Two-dimensional atom localization via controlled spontaneous emission from a driven tripod system,” Journal of the Optical Society of America B 28, 10-17 (2011).
17. R. G. Wan, J. Kou, L. Jiang, Y. Jiang, and J. Y. Gao*, “Two-dimensional atom localization via interacting double dark resanances,” Journal of the Optical Society of America B 28, 622-628 (2011).
18. R. G. Wan, J. Kou, L. Jiang, Y. Jiang, and J. Y. Gao*, “Two-dimensional atom localization via quantum interference in a coherently driven inverted-Y system,” Optics Communications 284, 985-990 (2011).
19. R. G. Wan, J. Kou, L. Jiang, S. Q. Kuang, Y. Jiang, and J. Y. Gao*, “Coherently induced double photonic band gaps in a driven N-type atomic system,” Optics Communications 284, 1569 (2011).
20. R. G. Wan, J. Kou, S. Q. Kuang, L. Jiang, and J. Y. Gao*, “Controlled light-pulse propagation via dynamically induced double photonic band gaps,” Optics Express 18, 15591 (2010).
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