Abstract
Modern optical communication system requires multiple channel transmission in different spectral band for different applications. Here we are proposing a microresonator structure for closely spaced, mode independent multiple channel transmission in 3rd transmission window by controlling the localization of photons in its cavity. To design the proposed structure, the spectral filtering properties of a single cavity planar microresonator are studied initially. In conventional multilayer dielectric filter, the localization of light in the microcavity is generally controlled by controlling the number of layers. Here we have shown that application of electric field across the structure, designed with suitable materials can also affect the localization of light in the cavity as well as the Q values of the transmission spectra. The mode independent characteristic of the structure is found from the study of its transmittance characteristics at different angle of incidence of light. It is found that the results of single cavity structure hold well for multicavity resonator structure also, in the regime of optical communication wavelength range. A method to increase the number of transmission channels is also proposed here keeping the fabrication perspective in mind.
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Armani, A.M., Vahala, K.J.: Heavy water detection using ultra-high-Q microcavities. Opt. Lett. 31(12), 1896–1898 (2006)
Bandyopadhyay, R., Chakraborty, R.: Design of tunable transmission filter using one-dimensional defective photonic crystal structure containing electro-optic material. Opt. Eng. 54(11), 117105 (2015)
Ctistis, G., Yuce, M., Hartsuiker, A., Claudon, J., Bazin, M., Gerard, J.M., Vos, W.L.: Ultimate fast optical switching of a planar microcavity in the telecom wavelength range. Appl. Phys. Lett. 98(16), 161114 (2011)
Enami, Y., Yuan, B., Tanaka, M., Luo, J., Jen, A.Y.: Electro-optic polymer/TiO2 multilayer slot waveguide modulators. Appl. Phys. Lett. 101, 123509 (2012)
Enami, Y., Nakamura, H., Luo, J., Jen, A.K.Y.: Analysis of efficiently poled electro-optic polymer/TiO2 vertical slot waveguide modulators. Opt. Commun. 362, 77–80 (2016)
Gerken, M., Miller, D.A.: Multilayer thin-film stacks with step like spatial beam shifting. J. Lightwave Technol. 22(2), 612–618 (2004)
Ghatak, A., Thyagarajan, K.: Optical Electronics, pp. 46–48. Cambridge University Press, Cambridge (1989)
Harding, P.J., Eusar, T.G., Nowicki, B.Y.R., Gerad, J.M., Vos, W.L.: Dynamical ultrafast all-optical switching of planar GaAs/AlAs photonic microcavities. arXiv:0706.2385 (2007)
Havermeyer, F., Liu, W., Moser, C., Psaltis, D., Steckman, G.J.: Volume holographic grating-based continuously tunable optical filter. Opt. Eng. 43(9), 2017–2021 (2004)
Hung, H.C., Wu, C.J., Yang, T.J., Chang, S.J.: Analysis of tunable multiple-filtering property in a photonic crystal containing strongly extrinsic semiconductor. J. Electromagn. Waves Appl. 25(14–15), 2089–2099 (2011)
Li, C., Liu, S., Kong, X., Zhang, H., Bian, B., Zhang, X.: A novel comb-like plasma photonic crystal filter in the presence of evanescent wave. IEEE Trans. Plasma Sci. 39(10), 1969–1973 (2011)
Lin, W.H., Wu, C.J., Yang, T.J., Chang, S.J.: Terahertz multichanneled filter in a superconducting photonic crystal. Opt. Express 18(26), 27155–27166 (2010)
Martini, F.D., Jacobovitz, G.R.: Anomalous spontaneous–stimulated-decay phase transition and zero-threshold laser action in a microscopic cavity. Phys. Rev. Lett. 60(17), 1711 (1988)
Noble, E., Nair, R.V., Jagtap, B.N.: Interaction between dual cavity modes in a planar photonic microcavity. J. Mod. Opt. 63, 1981–1991 (2016)
Nowicki, B.Y.R., Claudon, J., Bockler, C., Reitzenstein, S., Kamp, M., Morand, A., Forchel, A., Gerard, J.M.: High Q whispering gallery modes in GaAs/AlAs pillar microcavities. Opt. Express 15(25), 17291–17304 (2007)
Orfanidis, S.J.: Electromagnetic Waves and Antennas. Rutgers University, New Brunswick (2002)
Qiao, F., Zhang, C., Wan, J., Zi, J.: Photonic quantum-well structures: multiple channeled filtering phenomena. Appl. Phys. Lett. 77(23), 3698–3700 (2000)
Qiu, F., Spring, A.M., Maeda, D., Ozawa, M., Odoi, K., Aoki, I., Otomo, A., Shiyoshi Yokoyama, S.: TiO2 ring-resonator-based EO polymer modulator. Opt. Express 22(12), 14101–14107 (2014)
Reitzenstein, S., Hofmann, C., Gorbunov, A., Straub, M., Kwon, S.H., Schneider, C., Loffler, A., Hofling, S., Kamp, M., Forchel, A.: AlAs/GaAs micropillar cavities with quality factors exceeding 150.000. Appl. Phys. Lett. 90(25), 1109 (2007)
Rosenkrantz, E., Arnon, S.: Tunable electro-optic filter based on metal-ferroelectric nanocomposite for VLC. Opt. Lett. 39(16), 4954–4957 (2014)
Saleh, A., Stone, J.: Two-stage Fabry–Perot filters as demultiplexers in optical FDMA LANs. J. Lightwave Technol. 7, 323–330 (1989)
Scholtz, L., Korcekl, D., Ladayni, L., Mullerova, J.: Tunable thin film filters for the next generation PON stage 2 (NG-PON2). In: ELEKTRO, 2014. IEEE (2014)
Vahala, K.J.: Optical microcavities. Nature 424(6950), 839–846 (2003)
Wang, Q., Loh, T.-H., Ting Ng, D.K., Ho, S.H.: Design and analysis of optical coupling between silicon nanophotonic waveguide and standard single-mode fiber using an integrated asymmetric super-GRIN lens. IEEE J. Sel. Top. Quantum Electron. 17(3), 581–589 (2011)
Wu, C.J., Liao, J.J., Chang, T.W.: Tunable multilayer Fabry–Perot resonator using electro-optical defect layer. J. Electromagn. Waves Appl. 24(4), 531–542 (2010)
Wu, C.J., Lee, M.H., Jian, J.Z.: Design and analysis of multichannel transmission filter based on the single-negative photonic crystal. Prog. Electromagn. Res. 136, 561–578 (2013)
Yao, P., Rao, V.M., Hughes, S.: On-chip single photon sources using planar photonic crystals and single quantum dot. Laser Photonics Rev. 4(4), 499–516 (2010)
Yeh, P.: Optical Waves in Layered Media. Wiley, New York (1988)
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The first author (RB) acknowledges the TEQIP Phase II, University of Calcutta for funding his scholarship.
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Bandyopadhyay, R., Chakraborty, R. Realization of mode independent multichannel transmission filter by controlling the photon localization in symmetric cavities. Opt Quant Electron 49, 233 (2017). https://doi.org/10.1007/s11082-017-1073-9
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DOI: https://doi.org/10.1007/s11082-017-1073-9