1998年中国科学院物理研究所理学博士；
1989年电子科技大学理学硕士；
1986年北京师范大学理学学士

1998至2005年期间，先后在日本名古屋大学、以色列理工大学、德国海德堡大学（洪堡学者）以及新加坡国立大学从事研究工作。2006年加入北京理工大学物理学院。

主要从事软凝聚态物理前沿交叉学科研究。研究光和软物质相互作用新现象和机理、新型微/纳结构软物质功能材料及其在生物传感上的应用。研究方向包括：（1）自组装金属微/纳结构的光学活性及其在分子手性传感上的应用；（2）纳米等离激元动态手性调控及其在构建软纳米机器人中的应用。

已在ACS nano, Adv Funct Mater，Nanoscal, Soft Matter, Crystal Growth & Design，J Phys Chem B/C, Nano Research, Phys Chem Chem Phys，J Chem Phys等刊物上发表论文40余篇，论文引用1200余次, H指数为21（数据来源Google学术）。主要研究成果受到国内外同行关注，被顶级学术期刊  (如Chem Rev, Angew Chem Int Ed, Chem Soc Rev, ACS Nano, J Am Chem Soc 等）的多篇综述文章点评。受邀担任Nano Lett, J Am Chem Soc, ACS Photonics, ACS Nano, Nanoscale, Soft Matter, J Phys Chem Lett, Chem Commun, Anal Chem, Phys Chem Chem Phys, Sci Rep, Langmuir 等期刊审稿人。已主持/参与6项国家自然科学基金项目，目前在研项目为“等离激元介导的光与分子对映选择作用机理研究 （2021-2024年）。

代表性论文：

1. Liu S., Ma X., Song M., Ji C.Y., Song J., Ji Y. L., Ma S., Jiang J., Wu X. C., Li J, Liu M,* and Wang R. Y.,* Plasmonic Nanosensors with Extraordinary Sensitivity to Molecularly Enantioselective Recognition at Nanoscale Interfaces.  ACS Nano, 2021 , 15，19535−19545.

2. Song M., Tong L., Liu S., Zhang Y., Dong J., Ji Y. L., Guo Y., Wu X. C., Zhang X. D., and Wang R. Y.,* Nonlinear Amplification of Chirality in Self-Assembled Plasmonic Nanostructures, ACS Nano 2021, 15, 5715−5724.

3. Zhao W. J., Zhang W.X., Wang R. Y.,* Ji Y. L., Wu X. C., Zhang X. D.* Photocontrollable Chiral Switching and Selection in Self-Assembled Plasmonic Nanostructure,  Adv. Funct. Mater. 2019, 1900587.

4. Zhao W. J., Wang R. Y.,* We H, Li J. L., Ji Y. L., Jiang X., Wu X. C., Zhang X. D. Recognition of Chiral Zwitterionic Interactions at Nanoscale Interfaces by Chiroplasmonic Nanosensors, Phys. Chem. Chem. Phys. , 2017, 19, 21401-21406.

5. Wu T., Zhang W., Wang R. Y., Zhang X., * A giant chiroptical effect caused by the electric quadrupole, Nanoscale , 2017, 9, 5110-5118.

6. Zhang W., Wu T., Wang R. Y., Zhang X., * Amplification of the molecular chiroptical effect by low-loss dielectric nanoantennas,  Nanoscale , 2017, 9, 5701-5707.

7. Zhang W., Wu T., Wang R. Y., Zhang X., * Surface-Enhanced Circular Dichroism of Oriented Chiral Molecules by Plasmonic Nanostructures,  J. Phys. Chem. C  , 2017, 121, 666−675.

8. Wu T., Zhang X., Wang R. Y., Zhang X., * Strongly Enhanced Raman Optical Activity in Molecules by Magnetic Response of Nanoparticles, J. Phys. Chem. C  , 2016, 120, 14795−14804.

9. Zhai D., Wang  P., Wang R. Y., * Tian X., Ji Y., Zhao W., Wang L., Wei H., Wu X., Zhang, X. Plasmonic Polymers with Strong Chiroptical Response for Sensing Molecular Chirality , Nanoscale , 2015, 7, 10690-10698

10. Liu Y., Zhao, W., Ji, Y., Wang R.Y., Wu X., Zhang X. D., *Strong superchiral field in hot spots and its interaction with chiral molecules， Europhys. Lett. , 2015, 110, 17008

11. Wu T., Wang R. Y., Zhang X., * Plasmon-induced strong interaction between chiral molecules and orbital angular momentum of light,  Sci. Rep. , 2015, 5, 18003.

12. Wang R. Y.,* Wang P., Liu Y., Zhao W., Zhai D., Hong X., Ji Y., Wu X., Wang F., Zhang D., Zhang W., Liu R., Zhang X.,* Experimental Observation of Giant Chiroptical Amplification of Small Chiral Molecules by Gold Nanosphere Clusters,  J. Phys. Chem. C. , 2014, 118, 18, 9690-9695.

13. Hou S., Wen T., Zhang H., Liu W., Hu X., Wang R. Y., * Hu Z., * Wu X.* Fabrication of chiral plasmonic oligomers using cysteine-modified gold nanorods as monomers， Nano Research , 2014, 7, 1699-1705.

14. Liu Y., Wang R. Y., Zhang X.* Giant circular dichroism enhancement and chiroptical illusion in hybrid molecule-plasmonic nanostructures， Opt. Express , 2014, 22，4，4357-4370.

15. Wu T.，Ren J., Wang R. Y., Zhang X.* Competition of Chiroptical Effect Caused by Nanostructure and Chiral Molecules,  J. Phys. Chem. C.  2014, 118, 35, 20529–20537.

16. Wang P., Chen L. Wang R. Y., * Ji Y., Zhai D., Wu X., Liu Y., Chen K., Xu H.,* Giant optical activity from the radiative electromagnetic interactions in plasmonic nanoantennas,  Nanoscale , 2013, 5, 3889–3894.

17. Wang R.Y., * Wang H., Wu X. C., Ji Y., Wang P., Qu Y., Chung T. S. Chiral assembly of gold nanorods with collective plasmonic circular dichroism response， Soft Matter , 2011，7, 8370–8375.

18. Liu Y.,Wang R. Y.,* Li J. L., Yuan B., Han M., Wang P., Liu X.Y. Identify Kinetic Features of Fibers Growing, Branching, and Bundling in Microstructure Engineering of Crystalline Fiber Network,  CrystEngComm , 2014，16, 5402–5408

19. Wang R. Y., * Wang P.,Li J. L., Yuan B., Liu Y., Li L., Liu X.Y., From kinetic–structure analysis to engineering crystalline fiber networks in soft materials,  Phys. Chem. Chem. Phys. , 2013, 15, 3313-3319.

20. Li J. L., Liu X. Y. *, Wang X. G., Wang R. Y.，Controlling Nanoparticle Formation via Sizable Cages of Supramolecular Soft Materials， Langmuir , 2011，27, 7820–7827.

21. Wang R. Y., Liu X. Y.^*, Li J. L. Engineering Molecular Self-assembled Fibrillar Networks by Ultrasound， Cryst. Growth & Des. , 2009, 9, 3286-3291.

22. Xiong J. Y., Liu X. Y.^*, Li J. L., Narayanan J., Wang R. Y., Understanding of hydrogel network formation and its application in the architecture of significantly enhanced hydrogel, Appl. Phys. Lett., 2006, 89, 083106-083108.

23. Li J. L., Wang R. Y., Liu X. Y.^* Nanoengineering of a Biocompatible Organogel by Thermal Processing,  J. Phys. Chem. B. 2009, 113, 5011-5015.

24. Wang R. Y., Liu X. Y.^*, Narayanan J., Xiong J. Y., Li J. L. Architecture of Fiber Network: From Understanding to Engineering of Molecular Gels,  J. Phys. Chem. B . 2006, 110, 25797-25802.

25. Wang R. Y., Liu X. Y.^*, Xiong J. Y., Li J. L. Real-time observations of fiber network formation in molecular organogel: Supersaturation-dependent microstructure and its related rheological property, J. Phys. Chem. B. 2006, 110, 7275-7280.

26. Wang R.Y., Himmelhaus M.^*, Fick J., Herrwerth S., Grunze M. Interaction of Self-Assembled Monolayers of Oligo(ethylene glycol)- Terminated Alkanethiols with Water Studied by Vibrational Sum Frequency Generation (VSFG), J. Chem. Phys.  , 2005, 122, 164702.

27. Li J. L, Liu X. Y.^*, Wang R. Y., Xiong J. Y, Architecture of a Biocompatible Supramolecular Material by Supersaturation-driven Fabrication of Fiber Network,  J. Phys. Chem. B. 2005, 109, 24231-24235.

28. Wang, R. Y. * Distribution of Eu3+ ions in LaPO4 nanocrystals， J. Luminescence , 2004, 106, 211-217.

每年拟招收研究生（博士/硕士）2~3名。欢迎有志从事软物质物理与纳米光子学交叉前沿领域研究的同学报考，优先考虑具有光物理、化学物理、材料物理专业背景的考生。联系方式：wangry@bit.edu.cn