Fang Bo Professor

Dr. Fang Bo is a professor at Nankai University. He received his BS (also BE) and PHD degrees from Nankai University in 2002 and 2007, respectively. From June 2013 to August 2014, Dr. Bo was a visiting scholar at Washington University in St. Louis. He fabricated on-chip lithium niobate disk resonators with quality factors higher than one million and high-Q lithium-niobate-silica hybrid resonators using microfabrication technologies. Sum-frequency generation, electro-optic, thermo-optic effects were demonstrated in these fabricated resonators. He is the author of one chapter of a book and more than thirty journal publications, which was cited for more than 140 times as of September 2016. He gained 3 Grants from NSFC.

Research interest:optical microcavities and their applications, entangled photon pairs and singlephoton sources, nonlinear optical effects with low pump threshold, slow andfast light

College Physics (Electromagnetics, Optics and Quantum Physics)

[36] Z. Hao, J. Wang, S. Ma, W. Mao, F. Bo*, F. Gao, G. Zhang, and J. Xu, Sum-frequency generation in on-chip lithium niobate microdisk resonators, Photonics Res. 5, 623-628 (2017).

[35] X. Wang, B. Zhu, Y. Dong, S. Wang, Z. Zhu, F. Bo, and X. Li*, Generation of equilateral-polygon-like flat-top focus by tightly focusing radially polarized beams superposed with off-axis vortex arrays, Opt. Express 25, 26844-26852 (2017).

[34] F. Bo*, Ş. K. Özdemir*, F. Monifi, J. Zhang, G. Zhang, J. Xu, and L. Yang*, Controllable oscillatory lateral coupling in a waveguide-microdisk-resonatorsystem, Sci. Rep. 7, 8045 (2017).

[33] Y. Sun, F. Song, C. Qian, K. Peng, S. Sun, Y. Zhao, Z. Bai, J. Tang, S. Wu, H. Ali, F. Bo, H. Zhong, K. Jin, and X. Xu*, High-Q Microcavity Enhanced Optical Properties of CuInS2/ZnS Colloidal Quantum Dots toward Non-Photodegradation, ACS Photon. 4, 369-377 (2017).

[32] X. Gao, X., J. Li*, Z. Hao, F. Bo*, C. Hu, J. Wang, Z. Liu, Z.-Y. Li, G. Zhang and J. Xu, Vertical microgoblet resonator with high sensitivity fabricated by direct laser writing on a Si substrate. J. Appl. Phys. 121(6), 064502 (2017). .

[31] J. Wang, B. Zhu, Z. Hao, F. Bo*, X. Wang*, F. Gao, Y. Li, G. Zhang*, and J. Xu, Thermo-optic effects in on-chip lithium niobate microdisk resonators. Opt. Express 24(19), 21869-21879 (2016).

[30] F. Monifi, J. Zhang*, Ş. K. Özdemir*, B. Peng, Y.-x. Liu, F. Bo, F. Nori, and L. Yang*, Optomechanically induced stochastic resonance and chaos transfer between optical fields, Nat. Photon. 10, 399-405 (2016). (影响因子:32.386)

[29] L. Huang, J. Wang, W. Peng, W. Zhang, F. Bo, X. Yu, F. Gao*, P. Chang, X. Song, G. Zhang, and J. Xu, Mode conversion in a tapered fiber via a whispering gallery mode resonator and its application as add/drop filter, Opt. Lett. 41, 638-641 (2016).

[28] L. Huang, X. Song, P. Chang, W. Peng, W. Zhang, F. Gao*, F. Bo, G. Zhang, and J. Xu, All-fiber tunable laser based on an acousto-optic tunable filter and a tapered fiber, Opt. Express 24, 7449-7455 (2016).

[27] L. Huang, P. Chang, X. Song, W. Peng, W. Zhang, F. Gao*, F. Bo, G. Zhang, and J. Xu, Tunable in-fiber Mach-Zehnder interferometer driven by unique acoustic transducer and its application in tunable multi-wavelength laser, Opt. Express 24, 2406-2412 (2016).

[26] F. Bo, J. Wang, J. Cui, S. K. Ozdemir*, Y. Kong, G. Zhang*, J. Xu, and L. Yang*, Lithium-Niobate–Silica Hybrid Whispering-Gallery-Mode Resonators, Adv. Mater. 27, 8075-8081 (2015). (影响因子: 18.96)

[25] F. Bo*, Ş. K. Özdemir*, B. Peng, J. Wang, G. Zhang, J. Xu, and L. Yang*, Vertically coupled microresonators and oscillatory mode splitting in photonic molecules, Opt. Express 23, 30793-30800 (2015).

[24] F. Bo*, X. Wang, Y. Li, F. Gao, G. Zhang*, and J. Xu, Mode characteristics of silver-coated inverted-wedge silica microdisks, Sci. China-Phys. Mech. Astron. 58, 1-5 (2015). (Invited)

[23] L. Xu, Y. Dou, F. Bo, J. Xu, and G. Zhang*, Two-photon correlation and photon transport in disordered passive parity-time-symmetric lattices, Phys. Rev. A 91, 023817 (2015).

[22] J. Wang, F. Bo*, S. Wan, W. Li, F. Gao, J. Li, G. Zhang, and J. Xu, High-Q lithium niobate microdisk resonators on a chip for efficient electro-optic modulation, Opt. Express 23, 23072-23078 (2015).

[21] L. Huang, W. Peng, F. Gao*, F. Bo, G. Zhang, and J. Xu, Mutually modulated cross-gain modulation with a considerable modulation wave number-interaction length product, Opt. Express 23, 12004-12012(2015).

[20] L. Xu, Y. Yin, F. Bo, J. Xu, and G. Zhang*, Anomalous refraction indisordered one-dimensional photonic lattices, J. Opt. Soc. Am. B 31, 105-109 (2014).

[19] Y. Li, H. Liu*, H. Jia, F. Bo, G. Zhang, and J. Xu, Fully vectorial modeling of cylindrical microresonators with aperiodic Fourier modal method, J. Opt. Soc. Am. A 31, 2459-2466 (2014).

[18] Y. Dou, L. Xu, B. Han, F. Bo, J. Xu, and G. Zhang*, Quantum correlation of path-entangled two-photon states in waveguide arrays with defects, AIP Advances 4, 047117 (2014).

[17] F. Bo, S. H. Huang, S. K. ÖzdemirP, G. Zhang, J. Xu, and L. Yang, Inverted-wedge silica resonators for controlled and stable coupling, Opt. Lett. 39, 1841-1844 (2014).

[16] W. Zhang, L. Huang, F. Gao, F. Bo, G. Zhang, and J. Xu, Tunable broadband light coupler based on two parallel all-fiber acousto-optic tunable filters, Opt. Express 21, 16621-16628 (2013).

[15] W. Zhang, L. Huang, F. Gao, F. Bo, G. Zhang, and J. Xu, All-fiber tunable Mach-Zehnder interferometer based on an acousto-optic tunable filter cascaded with a tapered fiber, Opt. Commun. 292, 46-48(2013).

[14] L. Xu, Y. Yin, F. Bo, J. Xu, and G. Zhang, Transverse localization of light in the disordered one-dimensional waveguide arrays in the linear and nonlinear regimes, Opt. Commun. 296, 65-71 (2013).

[13] W. Zhang, L. Huang, F. Gao, F. Bo, L. Xuan, G. Zhang, and J. Xu, Tunable add/drop channel coupler based on an acousto-optic tunable filter and a tapered fiber, Opt. Lett. 37, 1241-1243 (2012).

[12] L. Xu, Y. Yin, F. Bo, J. Xu, and G. Zhang, Linear and nonlinear localized modes in the width-disordered one-dimensional waveguide arrays, SPIE proceedings-Photonics Asia, 855410-855410 (2012).

[11] F. Bo, L. Xu, J. Wang, G. Zhang, and J. Xu, Active chromatic control and resonant improvement on thetransverse-phase-modulation-induced group delay of light, SPIE proceedings-Photonics Asia, 85540O-85540O (2012).

[10] W. Zhang, F. Gao, F. Bo, Q. Wu, G. Zhang, and J. Xu, All-fiber acousto-optic tunable notch filter with a fiber winding driven by a cuneal acoustic transducer, Opt. Lett. 36, 271-273 (2011).

[9] F. Xin, G. Zhang, F. Bo, H. Sun, Y. Kong, J. Xu, T. Volk, and N. M. Rubinina, Ultraviolet photorefraction at 325 nm in doped lithium niobate crystals, J. Appl. Phys. 107, 033113 (2010).

[8] F. Bo, Z. Liu, F. Gao, G. Zhang, and J. Xu, Slow and fast light in photorefractive GaAs--AlGaAs multiple quantum wells in transverse geometry, J. Appl. Phys. 108, 063101 (2010).

[7] L. Xu, G. Q. Zhang, N. N. Xu, F. Bo, F. Gao, W. D. Fan, J. J. Xu, K.P. Lor, and K. S. Chiang, Active chromatic control on the group velocityof light at arbitrary wavelength in benzocyclobutene polymer, Opt. Express 17, 18292-18303 (2009).

[6] G. Q. Zhang, F. Bo, F. Gao, R. Dong, Y. F. Tu, and J. J. Xu, Slow and fast lights with moving and stationary refractive index gratings in solids at room temperature, Int. J. Mod. Phys. B 22, 447-468 (2008).

[5] F. Gao, J. Xu, G. Q. Zhang, F. Bo, and H. Liu, Paraxialenergy transport of a focused Gaussian beam in ruby with nondegenerate two-wave coupling like mechanism, Appl. Phys. Lett. 92 (2008).

[4] F. Bo, G. Zhang, and J. Xu, Ultraslow Gaussian pulse propagation induced by a dispersive phase coupling in photorefractive bismuth silicon oxide crystals at room temperature, Opt. Commun. 261,349-352 (2006).

[3] F. Bo, G. Zhang, and J. Xu, Transition between superluminal and subluminal light propagation in photorefractive Bi_{12}SiO_{20} crystals, Opt. Express 13, 8198-8203 (2005).

[2] G. Zhang, R. Dong, F. Bo, and J. Xu, Slowdown of group velocity of light by means of phase coupling in photorefractive two-wave mixing, Appl. Optics. 43, 1167-1173 (2004).

[1] G. Zhang, F. Bo, R. Dong, and J. Xu, Phase-coupling-induced ultraslow light propagation in solids at room temperature, Phys. Rev. Lett. 93, 133903-133903 (2004)