https://photonics.usst.edu.cn

https://photonics.usst.edu.cn

承担国家自然科学基金3项，上海市自然科学基金和上海市人才计划项目多项。

1. Shengli Pu, Lianmin Mao, Tianjun Yao, Jinfeng Gu, Mahieddine Lahoubi, and Xianglong Zeng, “Microfiber coupling structures for magnetic field sensing with enhanced sensitivity,” IEEE Sensors Journal 17(18), 5857-5861 (2017).

2. Jie Rao, Shengli Pu, Tianjun Yao, and Delong Su, “Ultrasensitive magnetic field sensing based on refractive-index-matched coupling,” Sensors 17(7), 1590 (2017).

3. Delong Su, Shengli Pu, Lianmin Mao, Zhaofang Wang, and Kai Qian, “A photonic crystal magnetic field sensor using a shoulder-coupled resonant cavity infiltrated with magnetic Fluid,” Sensors 16(12), 2157 (2016).

4. Lianmin Mao, Shengli Pu, Delong Su, Zhaofang Wang, Xianglong Zeng, and Mahieddine Lahoubi, “Magnetic field sensor based on cascaded microfiber coupler with magnetic fluid,” J. Appl. Phys. 120(9), 093102 (2016).

5. Shengli Pu, Longfeng Luo, Jiali Tang, Lianmin Mao, and Xianglong Zeng, “Ultrasensitive refractive-index sensors based on tapered fiber coupler with Sagnac loop,” IEEE Photon. Technol. Lett. 28(10), 1073-1076 (2016).

6. Longfeng Luo, Shengli Pu, Jiali Tang, Xianglong Zeng, and Mahieddine Lahoubi, “Highly sensitive magnetic field sensor based on microfiber coupler with magnetic fluid,” Appl. Phys. Lett. 106, 193507 (2015).

7. Longfeng Luo, Shengli Pu, Jiali Tang, Xianglong Zeng, and Mahieddine Lahoubi, “Reflective all-fiber magnetic field sensor based on microfiber and magnetic fluid,” Opt. Express 23(14), 18133-18142 (2015).

8. Longfeng Luo, Shengli Pu, Shaohua Dong, and Jiali Tang, “Fiber-optic magnetic field sensor using magnetic fluid as the cladding,” Sensors and Actuators A: Physical236, 67-72 (2015).

9. Jiali Tang, Shengli Pu, Longfeng Luo, and Shaohua Dong, “Simultaneous measurement of magnetic field and temperature based on magnetic fluid-clad long period fiber grating,” J. Eur. Opt. Soc.-Rapid 10, 15025 (2015).

10. Weizheng Lei, and Shengli Pu, “Tunable slow light with large bandwidth and low-dispersion in photonic crystal waveguide infiltrated with magnetic fluids,” J. Magn. 20(2), 110-113 (2015).

11. Jiali Tang, Shengli Pu, Shaohua Dong, and Longfeng Luo, “Magnetic field sensing based on magnetic-fluid-clad multimode-singlemode-multimode fiber structures,” Sensors 14, 19086-19094 (2014).

12. Shaohua Dong, Shengli Pu, and Haotian Wang，“Magnetic field sensing based on magnetic-fluid-clad fiber-optic structure with taper-like and lateral-offset fusion splicing,” Opt. Express 22, 19108-19116 (2014).

13. Shengli Pu, and Shaohua Dong, “Magnetic field sensing based on magnetic-fluid-clad fiber-optic structure with up-tapered joints,” IEEE Photon. J. 6, 5300206 (2014).

14. Shengli Pu, Shaohua Dong, and Juan Huang, “Tunable slow light based on magnetic-fluid-infiltrated photonic crystal waveguides,” J. Opt. 16, 045102 (2014).

15. Yang Liu, Lei Shi, Xinbiao Xu, Ping Zhao, Zheqi Wang, Shengli Pu, and Xinliang Zhang, “All-optical tuning of magnetic-fluid-filled optofluidic ring resonator,” Lab Chip 14, 3004-3010 (2014).

16. Shaohua Dong, Shengli Pu,and Juan Huang, “Magnetic field sensing based on magneto-volume variation of magnetic fluids investigated by air-gap Fabry-Pérot fiber interferometers,” Appl. Phys. Lett. 103, 111907 (2013).

17. Haotian Wang, Shengli Pu, Ning Wang, Shaohua Dong,and Juan Huang, “Magnetic field sensing based on singlemode–multimode–singlemode fiber structures using magnetic fluids as cladding,” Opt. Lett. 38, 3765-3768 (2013).

18. Shengli Pu, Haotian Wang, Ning Wang, and Xianglong Zeng, “Extremely large bandwidth and ultralow-dispersion slow light in photonic crystal waveguides with magnetically controllability,” Appl. Phys. B 112, 223-229 (2013).

19. Shengli Pu, Haotian Wang, Ning Wang, and Xianglong Zeng, “Tunable flat band slow light in reconfigurable photonic crystal waveguides based on magnetic fluids,” Opt. Commun. 311, 16-19 (2013).

20. Haotian Wang, Shengli Pu, Arash Gharibi, and Ning Wang, “Generation and versatile transmission properties of ring-shaped beams based on thermal lens effect of magnetic fluids and ring-limited windows,” Opt. Commun. 286, 211-216 (2013).

21. Hongzhu Ji, Shengli Pu, Xiang Wang, Guojun Yu, Ning Wang, and Haotian Wang, “Magnetic field sensing based on capillary filled with magnetic fluids,” Appl. Opt. 51, 6528-6538 (2012).

22. Hongzhu Ji, Shengli Pu, Xiang Wang, and Guojun Yu, “Influence of switchable magnetic field on the modulation property of nanostructured magnetic fluids,” Opt. Commun. 285, 4435-4440 (2012).

23. Xiang Wang, Shengli Pu, Hongzhu Ji, and Guojun Yu, “Enhanced magnetic-field-induced optical properties of nanostructured magnetic fluids by doping nematic liquid crystals,” Nanoscale Res. Lett. 7, 249 (2012).

24. Hongzhu Ji, Shengli Pu, Xiang Wang, and Guojun Yu, “Magnetic field sensing based on V-shaped groove filled with magnetic fluids,” Appl. Opt. 51, 1010-1020 (2012).

25. Shengli Pu, Xuekun Bai, and Lunwei Wang, “Temperature dependence of photonic crystals based on thermoresponsive magnetic fluids,” J. Magn. Magn. Mater. 323, 2866-2871 (2011).

26. Xuekun Bai, Shengli Pu, and Lunwei Wang, “Optical relaxation properties of magnetic fluids under externally magnetic fields,” Opt. Commun. 284, 4929-4935 (2011).

27. Xuekun Bai, Shengli Pu, Lunwei Wang, Xiang Wang, Guojun Yu, and Hongzhu Ji, “Tunable magneto-optic modulation based on magnetically responsive nanostructured magnetic fluids,” Chin. Phys. B 20, 107501 (2011).

28. Shengli Pu, Min Dai, and Guoqing Sun, “Longitudinal field-induced polarized light transmittance of magnetic fluids,” Opt. Commun. 283, 4012-4016 (2010).

29. Shengli Pu, and Ming Liu, “Tunable photonic crystals based on MnFe2O4 magnetic fluids by magnetic fields,” J. Alloys Compd. 481, 851-854 (2009).

30. Shengli Pu, Lanfang Yao, Feifei Guan, and Ming Liu, “Threshold-tunable optical limiters based on nonlinear refraction in ferrosols,” Opt. Commun. 282, 908-913 (2009).

31. Shengli Pu, Tao Geng, Xianfeng Chen, Xianglong Zeng, Ming Liu, and Ziyun Di, “Tuning the band gap of self-assembled superparamagnetic photonic crystals in colloidal magnetic fluids using external magnetic fields,” J. Magn. Magn. Mater. 320, 2345-2349 (2008).

32. Shengli Pu, Xianfeng Chen, Ziyun Di, Tao Geng, and Yuxing Xia, “Electrical properties of nanostructured magnetic colloid and influence of magnetic field,” Chin. Phys. Lett. 24, 3253-3256 (2007).

33. Shengli Pu, Xianfeng Chen, Ziyun Di, and Yuxing Xia, “Relaxation property of the magnetic-fluid-based fiber-optic evanescent field modulator,” J. Appl. Phys. 101, 053532 (2007).

34. Shengli Pu, Xianfeng Chen, Yuping Chen, Yonghao Xu, Weijun Liao, Lijun Chen, and Yuxing Xia, “Fiber-optic evanescent field modulator using a magnetic fluid as the cladding,” J. Appl. Phys. 99, 093516 (2006).

35. Shengli Pu, Xianfeng Chen, Lijun Chen, Weijun Liao, Yuping Chen, and Yuxing Xia, “Suppressing the thermal lens effect by magnetic-field-induced mass transfer and phase separation in a magnetic fluid,” Appl. Phys. Lett. 87, 021905 (2005).

36. Shengli Pu, Xianfeng Chen, Lijun Chen, Weijun Liao, Yuping Chen, and Yuxing Xia, “Tunable magnetic fluid grating by applying a magnetic field,” Appl. Phys. Lett. 87, 021901 (2005).

37. Shengli Pu, Xianfeng Chen, Yuping Chen, Weijun Liao, Lijun Chen, and Yuxing Xia, “Measurement of the refractive index of a magnetic fluid by the retroreflection on the fiber-optic end face,” Appl. Phys. Lett. 86, 171904 (2005).

38. Shengli Pu, Xianfeng Chen, Weijun Liao, Lijun Chen, Yuping Chen, and Yuxing Xia, “Laser self-induced thermo-optical effects in a magnetic fluid,” J. Appl. Phys. 96, 5930-5932 (2004).

国际期刊Journal of Nanofluids编辑、上海市物理学会第16届理事会理事、Journal of Nanomaterials客座主编(Special Issue, 2014年5-12月)。