光谱学与光谱分析 |
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The Precise Assignment of Whispering Gallery Modes for Lasing Spectra Emitting from Cylindrical Micro-Cavities |
WANG Dong-lin, JIANG Nan, JIANG Li-qun, ZHANG Zhen-li, PU Xiao-yun* |
Department of Physics, Yunnan University, Kunming 650091, China |
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Abstract Lasers with spherical or cylindrical dielectric resonators supported by whispering gallery modes (WGM) have attracted much interest due to their microscopic size, high cavity Q factor, and low lasing threshold. Cylindrical microcavity lasers based on the gain only in the evanescent field region of whispering gallery modes have been demonstrated in our recent works. The gain was excited by the evanescent wave of longitudinal optical pumping along the optical fiber. To well understand the obtained lasing spectra, the mode assignment is required. The explicit asymptotic formulas for the position and mode-interval of whispering gallery modes were obtained from the characteristic equation of whispering gallery modes in a cylindrical micro-cavity. The formulas were used to analyze the lasing spectra emitting from cylindrical microcavies which were evanescent-wave-gain pumped. The lasing spectra were found to be transverse magnetic modes(TM), and then the spectra were mode assigned with two integers, i.e., radial quantum numbers (l) and angular momentum numbers (n). Based on the explicit asymptotic formulas, all of the spectra from five optical fibers with a diameter ranging from 215 to 328 mm were well mode assigned. In the match between experimental spectral data and the asymptotic formula, only two matched parameters (l, n) were used, and the wavelength deviation in the match was less than 0.05 nm, which indicated that the mode assignment was reliable and precise. The spectral mode-assignment of cylindrical micro-cavity is important for computing the spatial distribution of mode intensity and is crucial for the applications of frequency-shift biosensor built in cylindrical micro-cavities. The method introduced in this paper can also be used to measure the diameters and refractive indexes of cylindrical micro-cavies precisely.
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Received: 2007-08-06
Accepted: 2007-11-11
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Corresponding Authors:
PU Xiao-yun
E-mail: xypu@163.com
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[1] Moon H J, Chough Y T, An K W. Physical Review Letters, 2000, 85(15): 3161. [2] Moon H J, Chough Y T, Kim J B. Applied Physics Letters, 2000, 76(25): 3679. [3] Moon H J, Park C W, Lee S B. Applied Physics Letters, 2004, 84(22): 4547. [4] Shevchenko A, Lindfors K, Buchter S C, et al. Optics Communications,2005, 45: 349. [5] LIU Ke-ling(刘克玲). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2005,25(1): 95. [6] JIANG Nan, WANG Dong-lin, PU Xiao-yun(江 楠,王东林,普小云). Chinese Journal of Lasers(中国激光), 2007, 34(7): 42. [7] Mazumder M M, Schaschek K, Chang R K, et al. Chemical Physics Letters, 1995, 239, 361. [8] Barber P W, Hill S C. Light Scattering by Particles: Computational Methods, Singapore: World Scientific Publishing Co. Pte. Ltd., 1990, 51. [9] White I M, Oveys H, Fan X Y. Optics Letters, 2006, 31(9): 1319. [10] ZHANG Lei, LIN Guo-ping, CAI Zhi-ping, et al(张 磊,林国平,蔡志平,等). Acta of Optica Snica(光学学报), 2007, 27(1), 94. [11] Eversole J D, Lin H B, Campillo A J. Applied Optics, 1992, 31(12): 1982. [12] Polson R C, Levina G, Vardeny Z V. Applied Physics Letters, 2000, 76(26): 3858. [13] LIANG Kun-miao(梁昆淼). The Mathematical Methods of Physics(数学物理方法). Beijing: People’s Education Press(北京:人民教育出版社), 1978. 364. [14] Lam C C, Leung P Y, Yang K. Journal of Optical Society of America, 1992, 9(9): 1585. |
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