Publication - Optical Fiber Technology Research Labarotary

2017

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[1] B. Yao, Y. Liu, S. W. Huang, C. Choi, Z. Xie, J. F. Flores, Y. Wu, M. Yu, D. L. Kwong, Y. Huang, Y. J. Rao, X. Duan and C.W.Wong, “Broadband gate-tunable terahertz plasmons in graphene heterostructures,” Nature Photonics 12, 22–28 (2017).
[2] B. C. Yao, Y. J. Rao, S. W. Huang, Y. Wu, Z. Y. Feng, C. Choi, H. Liu, H. F. Qi, X. F. Duan, G. D. Peng and C. W. Wong, “Graphene Q-switched distributed feedback fiber lasers with narrow linewidth approaching the transform limit,” Optics Express,
[3] Y. Gong, L. Qiu, L. C. Zhang, Y. Wu, J. Y. Rao and G. Peng, “Dual-mode fiber optofluidic flowmeter with a large dynamic range,” Journal of Lightwave Technology, 35(11), 2156-2160 (2017).
[4] H. Wu, Z. Wang, Q. He, W. Sun and Y. Rao, “Common-cavity ytterbium/Raman random distributed feedback fiber laser,” Laser Physics Letters, 13(5), 055101 (2016).
[5] C. Yu, Y. Wu, X. Liu, F. Fu, Y. Gong, Y. J. Rao and Y. Chen, “Miniature fiber-optic NH3 gas sensor based on Pt nanoparticle-incorporated graphene oxide,” Sensors and Actuators B: Chemical 244, 107-113 (2017).
[6] C. Yu, Y. Wu, C. Li, F. Wu, J. Zhou, Y. Gong, Y. J. Rao and Y. Chen, “Highly sensitive and selective fiber-optic Fabry-Perot volatile organic compounds sensor based on a PMMA film,” Optical Materials Express, 7(6), 2111-2116 (2017).
[7] L. C. Zhang, Y. Gong, W. Zou, Y. Wu, J. Y. Rao, G. Peng and X. Fan, “Microbubble-based fiber optofluidic interferometer for sensing,” Journal of Lightwave Technology, 35(13), 2514-2519 (2017).
[8] B. C. Yao, C. B. Yu, Y. Wu, S. W. Huang, H. Wu, Y. Gong, Y. F. Chen, Y. R. Li, C. W. Wong, X. D. Fan and Y. J. Rao, “Graphene-enhanced Brillouin optomechanical microresonator for ultrasensitive gas detection,” Nano Letters, 7b02176, (2017).
[9] C. Gong, Y. Gong, Q. Chen, Y. J. Rao, G. D. Peng and X. Fan, “Reproducible fiber optofluidic laser for disposable and array applications,” Lab on a Chip, 17(20), 3431-3436 (2017).
[10] Y. Wu, C. Yu, F. Wu, C. Li, J. Zhou, Y. Gong, Y. Rao and Y. Chen, “A Highly Sensitive Fiber-Optic Microphone Based on Graphene Oxide Membrane,” Journal of Lightwave Technology, 35(19), 4344-4349 (2017).

2016

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[1] R. Ma, W. L. Zhang, X. P. Zeng, Z. J. Yang, Y. J. Rao, B. C. Yao, C. B. Yu, Y. Wu and S. F. Yu, “Quasi mode-locking of coherent feedback random fiber laser,” Scientific Reports 6, 39703 (2016).
[2] X. P. Zeng, W. L. Zhang*, R. Ma, Z. J. Yang, X. Zeng, X. Dong, and Y. J. Rao, “Regulation of a pulsed random fiber laser in the Q-switched regime,” Laser Physics Letters, 13(11), 115105 (2016).
[3] Z. N. Wang, W. Sun, H. Wu, X. Y. Qian, Q. H. He, Z. D. Wei, and Y. J. Rao, “Long-distance random fiber laser point sensing system incorporating active fiber,” Optics Express, 24(20), 22448-22453 (2016).
[4] W. L. Zhang, Y. B. Song, X. P. Zeng, R. Ma, Z. J. Yang, and Y. J. Rao, “Temperature-controlled mode selection of Er-doped random fiber laser with disordered Bragg gratings,” Photonics Research, 4(3), 102-105 (2016).
[5] H. Wu, Z. N. Wang, Q. H. He, M. Q. Fan, Y. Q. Li, W. Sun, L. Zhang, Y. Li, and Y. J. Rao, “Polarization-modulated random fiber laser,” Laser Physics Letters, 13(5), 055101 (2016).
[6] W. L. Zhang, M. Y. Zheng, R. Ma, C. Y. Gong, Z. J. Yang, Y. Gong, G. D. Peng and Y. J. Rao, “Fiber-Type Random Laser Based on a Cylindrical Waveguide with a Disordered Cladding Layer,” Scientific Reports 6, 26473 (2016).
[7] B. C. Yao, Y. Wu, C. B. Yu, J. R. He, Y. J. Rao, Y. Gong, F. Fu, Y. F. Chen and Y. R. Li, “Partially reduced graphene oxide based FRET on fiber-optic interferometer for biochemical detection,” Scientific Reports 6, 23706 (2016).
[8] C. B. Yu, Y. Wu, X. L. Liu, B. C. Yao, F. Fu, Y. Gong, Y. J. Rao and Y. F. Chen, “Graphene oxide deposited microfiber knot resonator for gas sensing,” Optical Materials Express, 6(3), 727-733 (2016).
[9] C. L. Zhang, Y. Gong, Q. F. Liu, Y. Wu, Y. J. Rao and G. D. Peng, “Graded-Index Fiber Enabled Strain-Controllable Optofluidic Manipulation,” IEEE Photonics Technology Letters, 28(3), 256-259 (2016).
[10] Z. N. Wang, L. Zhang, S. Wang, N. T. Xue, F. Peng, M. Q. Fan, W. Sun, X. Y. Qian, J. R. Rao, and Y. J. Rao, “Coherent Phi-OTDR based on I/Q demodulation and homodyne detection,” Optics Express, 24(2), 853-858 (2016).

2015

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[1] Z. Wang, H. Wu, M. Fan, L. Zhang, Y. J. Rao, W. Zhang and X. Jia, “High power random fiber laser with short cavity length: theoretical and experimental investigations,” IEEE Journal of Selected Topics in Quantum Electronics, 21(1), 0900506 (2015).
[2] W. Zhang, S. Li, R. Ma, Y. J. Rao, Y. Zhu, Z. Wang, X. Jia and J. Li, “Random distributed feedback fiber laser based on combination of Er-doped fiber and single-mode fiber,” IEEE J. of Sel. Top. in Quan. Elect., 0900406 (2015).
[3] H. Wu, Z. N. Wang, D. V. Churkin, I. D. Vatnik, M. Q. Fan, and Y. J. Rao, “Random distributed feedback Raman fiber laser with polarized pumping,” Laser Physics Letters, 12(1), 015101 (2015).
[4] H. Wu, Z. Wang, M. Fan, L. Zhang, W. Zhang and Y. J. Rao, “Role of the mirror’s reflectivity in forward-pumped random fiber laser,” Opt. Express 23, 1421-1427 (2015).
[5] Y. Gong, C. Zhang, Q. Liu, Y. Wu, H. Wu, Y. J. Rao and G. D. Peng, “Optofluidic tunable manipulation of microparticles by integrating graded-index fiber taper with a microcavity,” Optics Express, 23(3), 3762-3769 (2015).
[6] Y. Wu, B. C. Yao, Q. Y. Feng, X. L. Cao, X. Y. Zhou, Y. J. Rao, Y. Gong, W. L. Zhang, Z. G. Wang, Y. F. Chen, and K. S. Chiang, “Generation of cascaded four-wave-mixing with graphene-coated microfiber,” Photon. Research 3, A64-A68 (2015).
[7] L. Zhang, Z. N. Wang, J. Li, J. J. Zeng, Y. Li, X. H. Jia and Y. J. Rao, “Ultra-long dual-sideband BOTDA with balanced detection,” Optics and Laser Technology, 68, 206-210 (2015).
[8] Z. N. Wang, M. Q. Fan, L. Zhang, H. Wu, D. V. Churkin, Y. Li, X. Y. Qian and Y. J. Rao, “Long-range and high-precision correlation optical time-domain reflectometry utilizing an all-fiber chaotic source,” Opt. Express 23, 15514-15520 (2015).
[9] W. L. Zhang, X. M. Wu, F. Wang, R. Ma, X. F. Li, and Y. J. Rao, “Stark effect induced microcavity polariton solitons,” Optics Express, 23(12), 15762-15767 (2015).
[10] W. L. Zhang, R. Ma, C. H. Tang, Y. J. Rao, X. P. Zeng, Z. J. Yang, Z. N. Wang, Y. Gong and Y. S. Wang, “All optical mode controllable Er-doped random fiber laser with distributed Bragg gratings,” Optics Letters, 40(13), 3181-3184 (2015).

2014

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[1]X. P. Liu, T. T. Wang, Y. Wu*, Y. Gong, Y. J. Rao, Dual-Parameter Sensor Based on Tapered FBG Combined With Microfiber Cavity, IEEE Photonics Technology Letters, Accepted, 2014.
[2] Y. Gong, C. B. Yu, T. T. Wang, X. P. Liu, Y. Wu, Y. J. Rao, M. L. Zhang, H. J. Wu, X. X. Chen, and G. D. Peng, Highly sensitive force sensor based on optical microfiber asymmetrical Fabry-Perot interferometer, Optics Express, 22(3), 3578-3586 (2014).
[3] B. C. Yao, Y. Wu*, Y. Cheng, A. Q. Zhang, Y. Gong, Y. J. Rao, Z. G. Wang, Y. F. Chen. All-optical Mach–Zehnder interferometric NH3 gas sensor based on graphene/microfiber hybrid waveguide, Sensors and Actuators B: Chemical, 194, 142-148 (2014).
[4] Y. Wu, B. C. Yao, Y. Cheng, Y. J. Rao, Y. Gong, W. L. Zhang, Z. G. Wang, Y. F. Chen, Hybrid graphene-microfiber waveguide for chemical gas sensing, Journal of Selected Topics on Quantum Electronics, 20(1), 4400206 (2014).
[5] Y. Wu, B. C. Yao, Y. Cheng, Y. J. Rao, Y. Gong, X. Zhou, B. Wu, and K. S. Chiang. Four-Wave Mixing in a Microfiber Attached Onto a Graphene Film, IEEE Photonics Technology Letters, 26(3), 249-252 (2014).
[6] Y. Wu, B. C. Yao, A. Q. Zhang, Y. J. Rao, Z. G. Wang, Y. Cheng, Y. Gong, W. L. Zhang, Y. F. Chen, and K. S. Chiang, Graphene-coated microfiber Bragg grating for high sensitivity gas sensing, Optics Letters, 39(5), 1235-1237 (2014).

2013

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[1] Y. Wu, B. C. Yao, Y. Cheng, Y. J. Rao, Y. Gong, W. L. Zhang, Z. G. Wang, Y. F. Chen, Hybrid graphene-microfiber waveguide for chemical gas sensing, Journal of Selected Topics on Quantum Electronics, (2013).
[2] Xin-Hong Jia, Yun-Jiang Rao, Fei Peng, Zi-Nan Wang, Wei-Li Zhang, Hui-Juan Wu, and Yun Jiang, Optics Express, 21(5), 6572-6577 (2013).
[3] Xinhong Jia, Yunjiang Rao, Zinan Wang, Weili Zhang, Chengxu Yuan, Xiaodong Yan, Jin Li, Han Wu, Yeyu Zhu, Fei Peng. Distributed Raman amplification using ultra-long fiber laser with a ring cavity: characteristics and sensing application [J]. Opt. Expr
[4] Xinhong Jia, Yunjiang Rao, Chengxu Yuan, Jin Li, Xiaodong Yan, Zinan Wang, Weili Zhang, Han Wu, Yeyu Zhu, Fei Peng. Hybrid distributed Raman amplification combining random fiber laser based 2nd-order and low-noise LD based 1st-order pumping [J]. Opt.
[5] W. L. Zhang, Y. Y. Zhu, Y. J. Rao, Z. N. Wang, X. H. Jia, and H. Wu, Random fiber laser formed by mixing dispersion compensated fiber and single mode fiber, Optics Express, 21(7), 8544-8549 (2013).
[6] Han Wu, Zinan Wang, Xinhong Jia, Peiyun Li, Mengqiu Fan, Yi Li, Yeyu Zhu. Flat amplitude multiwavelength Brillouin-Raman random fiber laser with a half-open cavity [J]. Appl. Phys. B, 112 (10):467-471(2013).
[7] Zinan Wang, Han Wu, Mengqiu Fan, Yunjiang Rao, Xinhong Jia, Weili Zhang. Third-order random lasing via Raman gain and Rayleigh feedback within a half-open cavity [J]. Opt. Express, 21(17):20090-20095 (2013).
[8] Y. Gong, A. Y. Ye, Y. Wu,Y. J.Rao, Y. Yao, S. Xiao, Graded-index fiber tip optical tweezers: Numerical simulation and trapping experiment, Optics Express, 21(13), 16181-16190 (2013).
[9] B. C.Yao, Y. Wu, Z. G. Wang, Y. Cheng, Y. J.Rao, Y. Gong, Y. F. Chen, and Y. R. Li,Demonstration of complex refractive index of graphene waveguide by microfiber-based Mach–Zehnder interferometer, Optics Express, 21(24),29818-29826 (2013).
[10] Y. Cheng, B. C. Yao, Y. Wu, Z. G. Wang, Y. Gong, Y. J.Rao,Simulation and experimental research of phase transmission features based on evanescent field coupled graphene waveguide, ActaPhysicaSinica, 62(23), 237805 (2013).

2012

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[1] Y. J. Rao, W. L. Zhang, J. M. Zhu, Z. X. Yang, Z. N. Wang, X. H. Jia, Hybrid lasing in an ultra-long ring fiber laser, Optics Express, 20(20), 22563-22568 (2012)
[2] W. L. Zhang, Y. J. Rao, J. M. Zhu, Z. X. Yang, Z. N. Wang, X. H. Jia, Low threshold 2nd-order random lasing of a fiber laser with a half-opened cavity, Optics Express, 20(13), 14400-14405 (2012)
[3] Z. N. Wang, Y. J. Rao, H. Wu, P. Y. Li, X. H. Jia, W. L. Zhang, Long-distance fiber-optic point-sensing systems based on random fiber lasers, Optics Express, 20(16), 17695-17700 (2012)
[4] Y. J. Rao, Study on fiber-optic low-coherence interferometric and fiber Bragg grating sensors, Photonic Sensors, 1(4), 382-400 (2012)
[5] L. Liu, Y. Gong, et al., Spatial Frequency Multiplexing of Fiber-Optic Interferometric Refractive Index Sensors Based on Graded-Index Multimode Fibers, Sensors, 12, 12377-12385 (2012)
[6] B. C. Yao, Y. Wu, L. Jia, Y. J. Rao, Y. Gong, C. Y. Jiang, Mode field distribution of optical transmission along microfiber affected by CNT films with complex refraction index, Journal of the Optical Society of America B, 29(5), 891-895 (2012)
[7] D. W. Duan, Y. J. Rao, T. Zhu, High sensitivity gas refractometer based on all-fiber open-cavity Fabry-Perot interferometer formed by large lateral offset splicing, Journal of the Optical Society of America B, 29(5), 912-915 (2012)
[8] Y. J. Rao, OFS research over the last 10 years at CQU & UESTC, Photonic Sensors, 2(2), 97-117 (2012)
[9] W. L. Zhang, Y. J. Rao, Optical Tamm state polaritons in a quantum well microcavity with gold layers, Chinese Physics B, 21(5), 057107 (2012)
[10] Y. Wu, L. Jia, T. H. Zhang, Y. J. Rao, Y. Gong, Microscopic multi-point temperature sensing based on microfiber double-knot resonators, Optics Communications, 285(8), 2218-2222 (2012)

2011

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[1] D. W. Duan, Y. J. Rao, L. C. Xu, T. Zhu, D. Wu, J. Yao, In-fiber Mach-Zehnder interferometer formed by large lateral offset fusion splicing for gases refractive index measurement with high sensitivity, Sensors and Actuators B-Chemical, 160(1), 1198-12
[2] Y. E. Fan, T. Zhu, L. L. Shi, Y. J. Rao, Fabrication and Characteristics of Phase-Shifted Beat Gratings Induced by CO2 Laser, Microwave and Optical Technology Letters, 53(11), 2526-2530 (2011)
[3] Y. J. Rao , Z. L. Ran, Fiber-optic Fabry-Perot sensors take the strain under high temperature, Laser Focus World, 47(11), 71-74 (2011)
[4] D. W. Duan, Y. J. Rao, L. C. Xu, T. Zhu, M. Deng, D. Wu, J. Yao, In-Fiber Fabry-Perot and Mach-Zehnder interferometers based on hollow optical fiber fabricated by arc fusion splicing with small lateral offsets, Optics Communications, 284(22), 5311-531
[5] L. L. Shi, T. Zhu, Y. E. Fan, K. S. Chiang, Y. J. Rao, Torsion sensing with a fiber ring laser incorporating a pair of rotary long-period fiber gratings, Optics Communications, 284(22), 5299-5302 (2011)
[6] Y. E. Fan, T. Zhu, L. L. Shi, Y. J. Rao, Highly sensitive refractive index sensor based on two cascaded special long-period fiber gratings with rotary refractive index modulation, Applied Optics, 50(23), 4604-4610 (2011)
[7] Y. Wu, T. H. Zhang, Y. J. Rao, Y. Gong, Miniature interferometric humidity sensors based on silica/polymer microfiber knot resonators, Sensors and Actuators B-Chemical, 155(1), 258-263 (2011)
[8] M. Deng, C. P. Tang, T. Zhu, Y. J. Rao, Highly sensitive bend sensor based on Mach-Zehnder interferometer using photonic crystal fiber, Optics Communications, 284(12), 2849-2853 (2011)
[9] H. J. Wu, Y. J. Rao, C. Tang, Y. Wu, Y. Gong, A novel FBG-based security fence enabling to detect extremely weak intrusion signals from nonequivalent sensor nodes, Sensors and Actuators A-Physical, 167(2), 548-555 (2011)
[10] M. Deng, C. P. Tang, T. Zhu, Y. J. Rao, PCF-Based Fabry-Perot Interferometric Sensor for Strain Measurement at High Temperatures, IEEE Photonics Technology Letters, 23(11), 700-702 (2011)

Before 2011

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[1] Y. Gong, Y. Guo, Y. J. Rao, T. Zhao, Y. Wu, Fiber-Optic Fabry-Perot Sensor Based on Periodic Focusing Effect of Graded-Index Multimode Fibers, IEEE Photonics Technology Letters, 22(23), 1708-1710 (2010).
[2] T. Ke, T. Zhu, Y. J. Rao, M. Deng, Accelerometer Based on All-Fiber Fabry-Perot Interferometer Formed by Hollow-Core Photonic Crystal fiber, Microwave and Optical Technology Letters, 52(11), 2531-2535 (2010).
[3] T. Zhu, T. Ke, Y. J. Rao, K. S. Chiang, Fabry-Perot optical fiber tip sensor for high temperature measurement, Optics Communications, 283(19), 3683-3685 (2010).
[4] Y. Gong, T. Zhao, Y. J. Rao, Y. Wu, Y. Guo, A ray-transfer-matrix model for hybrid fiber Fabry-Perot sensor based on graded-index multimode fiber, Optics Express, 18(15), 15844-15852 (2010).
[5] Y. H. Chen, Y. Wu, Y. J. Rao, Q. Deng, Y. Gong, Hybrid Mach-Zehnder interferometer and knot resonator based on silica microfibers, Optics Communications, 283(14), 2953-2956 (2010).
[6] Y. J. Rao, D. W. Duan, Y. E. Fan, T. Ke, M. Xu, High-Temperature Annealing Behaviors of CO2 Laser Pulse-Induced Long-Period Fiber Grating in a Photonic Crystal Fiber, Journal of Lightwave Technology, 28(10), 1530-1535 (2010).
[7] X. H. Jia, Y. J. Rao, L. Chang, C. Zhang, Z. L. Ran, Enhanced Sensing Performance in Long Distance Brillouin Optical Time-Domain Analyzer Based on Raman Amplification: Theoretical and Experimental Investigation, Journal of Lightwave Technology, 28(11)
[8] M. Deng, C. P. Tang, T. Zhu, Y. J. Rao, L. C. Xu, M. Han, Refractive index measurement using photonic crystal fiber-based Fabry-Perot interferometer, Applied Optics, 49(9), 1593-1598 (2010).
[9] Y. J. Rao, B. Xu, Z. L. Ran, Y. Gong, Micro Extrinsic Fiber-Optic Fabry-Perot Interferometric Sensor Based on Erbium- and Boron-Doped Fibers, Chinese Physics Letters, 27(2), 024208 (2010).
[10] Y. Wu, X. Zeng, Y. J. Rao, Y. Gong, C. L. Hou, G. G. Yang, MOEMS Accelerometer Based on Microfiber Knot Resonator, IEEE Photonics Technology Letters, 21(20), 1547-1549 (2009).