Optics and Precision Engineering, Volume. 17, Issue 2, 237(2009)
Research on some new mechanisms of slow light and its applications
[1] [1] HAU L V, HARRIS S E, DUTTON Z, et al.. Light speed reduction to 17 metres per second in an ultracold atomic gas[J]. Nature, 1999,397:594-598.
[2] [2] FAN B H, ZHANG Y D, YUAN P. Ultraslow light propagation in a solid[J]. Acta Physica Sinica,2005,54(10):4692-4695. (in Chinese)
[4] [4] SONG K Y, HERREZ M G, THVENAZ L. Observation of pulse delaying and advancement in optical fibers using stimulated Brillouin scattering[J]. Opt. Express, 2005,13(1):82-88.
[5] [5] ZHU ZH M, DAWES A M C, GAUTHIER D J, et al.. Broadband SBS slow light in an optical fiber[J]. Journal of Lightwave Technology, 2007,25(1):201-206.
[6] [6] ZHU ZH M, DAWES A M C, GAUTHIER D J, et al.. 12-Ghz-bandwidth SBS slow light in an optical fibers[C]. OFC06 PDP1:2657-2659.
[7] [7] SONG K Y, HOTATE K. SBS slow light in optical fibers with 25-GHz-bandwidth[C]. Optical Fiber Communication Conference National Fiber Optic Engineers Conference, OFCNFOEC 2007. Technical Digest, March 2007,34-6.
[8] [8] HERREZ M G, SONG K Y, THVENAZ L. Arbitrary-bandwidth brillouin slow light in optical fibers[J]. Optics Express,2006,14(4):1395-1400.
[9] [9] ZHANG G Q, BO F, DONG R, et al.. Dispersive effect of light phase coupling and group velocity control in solids at room temperature[J]. Wuli, 2006,35(10):845-851. (in Chinese)
[10] [10] SCHWEINSBERG A, LEPESHKIN N N, BIGELOW M S,et al.. Observation of superluminal and slow light propagation in erbium-doped optical fiber[J]. EUROPHYSICS LETTERS, 2006,73(20):218-224.
[11] [11] GEHRING G M, SCHWEINSBERG A, BARSI C, et al.. Observation of backward pulse propagation through a medium with a negative group velocity[J]. Science,2006,312(5775):895-897.
[12] [12] ZHANG Y D, QIU W, YE J B, et al.. Controllable ultraslow light propagation in highly-doped erbium fiber[J]. Optics Communications,2008,281(9):2633-2637.
[13] [13] QIU W, ZHANG Y D, YE J B, et al.. Controllable group velocity of light pulse in erbium-doped optical fiber at room temperature[J]. Acta Physica Sinica,2007,56(12):7009-14.
[14] [14] VLASOV Y A, O'BOYLE M, HAMANN H F, et al.. Active control of slow light on a chip with photonic crystal waveguides[J]. Nature, 2005, 438(7064):65-69.
[15] [15] POVINELLI M L, JOHNSON S G, JOANNOPOULOS J D. Slow-light, band-edge waveguides for tunable time delays[J]. Opt. Exp., 2005,13(18):7145-7159.
[16] [16] GERSEN H, KARLE T J, ENGELEN R J P,et al.. Real-space observation of ultraslow light in photonic crystal waveguides[J]. Physical Review Letters,2005,94(7):073903-1-4.
[17] [17] FINLAYSON C E, CATTANEO F, PERNEY N M B, et al.. Slow light and choromatic temporal dispersion in photonic crystal waveguides using femtosecond time of flight[J]. Phys. Rev. E, 2006,73:016619-1-10.
[18] [18] ZHANG G D,LUAN P G. Wave transmission in photonic crystals[J]. Physics Bimonthly,2006,28(5):844-850.(in Chinese)
[19] [19] SCALORA M, FLYM R J, REINHARDT S B, et al.. Ultrashort pulse propagation at the photonic band edge large tunable group delay with minimal distortion and loss[J]. Phys. Rev. E, 1996,54:R1078-R1081.
[20] [20] ZHU S Y, LIU N H, ZHENG H, et al.. Time delay of light propagation through defect modes of one-dimensional photonic band-gap structure[J]. Optics Communications,2000,174(1-4):139-144.
[21] [21] SETTLE M D, ENGELEN R J P, SALIB M, et al.. Flatband slow light in photonic crystals featuring spatial pulse compression and Terahertz bandwidth[J]. Opt. Exp., 2007,15(1):219-226.
[22] [22] YANIK M F, FAN S H. Stopping and storing light coherently[J]. Phys. Rev. A, 2005,71(1):013803-1-10.
[23] [23] YANIK M F, FAN S H. Dynamic photonic structures stopping storage, and time reversal of light[J]. Studies in Applied Mathematics, 2005,115:233-253.
[24] [24] WANG Y, ZHANG W, HUANG Y D, et al.. SBS slow light in high nonlinearity photonic crystal fiber[C]. OFC/NFOEC 2007-Optical Fiber Communication and the National Fiber Optic Engineers Conference 2007,4348397:1-3.
[25] [25] TOTSUKA K, TOMITA M. Dynamics of fast and slow pulse propagation through a microsphere-optical-fiber system[J]. Physical Review E (Statistical, Nonlinear, and Soft Matter Physics),2007,75(1):16610-1-5.
[26] [26] CHANG-HANG C J, KU P C, KIM J, et al.. Variable optical buffer using slow light in semiconductor nanostructures[J]. IEEE,2003,91(11):1884-1897.
[27] [27] LU CH, MAO Y J. Slow light buffer and its applications in optical packet switching[J]. Bandaoti Guangdian/Semiconductor Optoelectronics,2007,28(3):420-422. (in Chinese)
[28] [28] WU CH Q. Fiber based all-optical buffer[J]. Bandaoti Guangdian/Semiconductor Optoelectronics,2007,28(5):601-606. (in Chinese)
[29] [29] PENG C, LI Z B, XU A S. Rotation sensing based on a slow-light resonating structure with high group dispersion[J]. Applied Optics,2007,46(19):4125-4131.
[30] [30] ZOU L F, BAO X Y, YANG S Q, et al.. Effect of Brillouin slow light on distributed Brillouin fiber sensors[J]. Optics Letters,2006,31(6):2698-2700.
[31] [31] THVENAZ L, SONG K Y, HERREZ M G. Time biasing due to the slow-light effect in distributed fiber-optic Brillouin sensors[J]. Optics Letters,2006,31(6):715-717.
[32] [32] ZADOK A, RAZ O, EYAL A,et al.. Optically controlled low-distortion delay of GHz-wide radio-frequency signals using slow light in fibers[J]. IEEE Photonics Technology Letters,2007,19(7):462-464
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ZHAO Yong, ZHAO Hua-wei, ZHANG Xin-yuan, YUAN Bo, ZHANG Shuo. Research on some new mechanisms of slow light and its applications[J]. Optics and Precision Engineering, 2009, 17(2): 237
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Received: May. 21, 2008
Accepted: --
Published Online: Oct. 9, 2009
The Author Email: Yong ZHAO (zhaoyong@ise.neu.edu.cn)
CSTR:32186.14.