Integrated flat-top reflection filters operating near bound states in the continuum

Leonid L. Doskolovich; Evgeni A. Bezus; Dmitry A. Bykov

doi:doi:10.1364/PRJ.7.001314

Photonics Research, 2019, 7 (11): 11001314, Published Online: Nov. 1, 2019

Integrated flat-top reflection filters operating near bound states in the continuum Download： 507次

Leonid L. Doskolovich ^1,2†Evgeni A. Bezus ^1,2,*†Dmitry A. Bykov ^1,2

Author Affiliations

¹ Image Processing Systems Institute—Branch of the Federal Scientific Research Centre “Crystallography and Photonics” of Russian Academy of Sciences, Samara 443001, Russia

² Samara National Research University, Samara 443086, Russia

Copy Citation Text

Leonid L. Doskolovich, Evgeni A. Bezus, Dmitry A. Bykov. Integrated flat-top reflection filters operating near bound states in the continuum[J]. Photonics Research, 2019, 7(11): 11001314.

References

[1] HausH. A., Waves and Fields in Optoelectronics (Prentice-Hall, 1984).

[2] T. Mossberg. Planar holographic optical processing devices. Opt. Lett., 2001, 26: 414-416.

[3] G. Calafiore, A. Koshelev, S. Dhuey, A. Goltsov, P. Sasorov, S. Babin, V. Yankov, S. Cabrini, C. Peroz. Holographic planar lightwave circuit for on-chip spectroscopy. Light Sci. Appl., 2014, 3: e203.

[4] S. Babin, A. Bugrov, S. Cabrini, S. Dhuey, A. Goltsov, I. Ivonin, E.-B. Kley, C. Peroz, H. Schmidt, V. Yankov. Digital optical spectrometer-on-chip. Appl. Phys. Lett., 2009, 95: 041105.

[5] C. Peroz, C. Calo, A. Goltsov, S. Dhuey, A. Koshelev, P. Sasorov, I. Ivonin, S. Babin, S. Cabrini, V. Yankov. Multiband wavelength demultiplexer based on digital planar holography for on-chip spectroscopy applications. Opt. Lett., 2012, 37: 695-697.

[6] C. Peroz, A. Goltsov, S. Dhuey, P. Sasorov, B. Harteneck, I. Ivonin, S. Kopyatev, S. Cabrini, S. Babin, V. Yankov. High-resolution spectrometer-on-chip based on digital planar holography. IEEE Photon. J., 2011, 3: 888-896.

[7] L. L. Doskolovich, E. A. Bezus, D. A. Bykov. Two-groove narrowband transmission filter integrated into a slab waveguide. Photon. Res., 2018, 6: 61-65.

[8] R. V. Schmidt, D. C. Flanders, C. V. Shank, R. D. Standley. Narrow-band grating filters for thin-film optical waveguides. Appl. Phys. Lett., 1974, 25: 651-652.

[9] C. S. Hong, J. B. Shellan, A. C. Livanos, A. Yariv, A. Katzir. Broad-band grating filters for thin film optical waveguides. Appl. Phys. Lett., 1977, 31: 276-278.

[10] L. A. Weller-Brophy, D. G. Hall. Analysis of waveguide gratings: application of Rouard’s method. J. Opt. Soc. Am. A, 1985, 2: 863-871.

[11] R. Zengerle, O. Leminger. Phase-shifted Bragg grating filters with improved transmission characteristics. J. Lightwave Technol., 1995, 13: 2354-2358.

[12] J. N. Damask, H. A. Haus. Wavelength-division multiplexing using channel-dropping filters. J. Lightwave Technol., 1993, 11: 424-428.

[13] E. A. Bezus, D. A. Bykov, L. L. Doskolovich. Bound states in the continuum and high-Q resonances supported by a dielectric ridge on a slab waveguide. Photon. Res., 2018, 6: 1084-1093.

[14] E. A. Bezus, L. L. Doskolovich, D. A. Bykov, V. A. Soifer. Spatial integration and differentiation of optical beams in a slab waveguide by a dielectric ridge supporting high-Q resonances. Opt. Express, 2018, 26: 25156-25165.

[15] C.-L. Zou, J.-M. Cui, F.-W. Sun, X. Xiong, X.-B. Zou, Z.-F. Han, G.-C. Guo. Guiding light through optical bound states in the continuum for ultrahigh-Q microresonators. Laser Photon. Rev., 2015, 9: 114-119.

[16] A. P. Hope, T. G. Nguyen, A. Mitchell, W. Bogaerts. Quantitative analysis of TM lateral leakage in foundry fabricated silicon rib waveguides. IEEE Photon. Technol. Lett., 2016, 28: 493-496.

[17] NguyenT. G.RenG.SchoenhardtS.KnoerzerM.BoesA.MitchellA., “Ridge resonance: a new resonance phenomenon for silicon photonics harnessing bound states in the continuum,” arXiv:1810.06734 (2018).

[18] C. W. Hsu, B. Zhen, A. D. Stone, J. D. Joannopoulos, M. Soljačić. Bound states in the continuum. Nat. Rev. Mater., 2016, 1: 16048.

[19] D. C. Marinica, A. G. Borisov, S. V. Shabanov. Bound states in the continuum in photonics. Phys. Rev. Lett., 2008, 100: 183902.

[20] C. W. Hsu, B. Zhen, J. Lee, S. L. Chua, S. G. Johnson, J. D. Joannopoulos, M. Soljačić. Observation of trapped light within the radiation continuum. Nature, 2013, 499: 188-191.

[21] J. W. Yoon, S. H. Song, R. Magnusson. Critical field enhancement of asymptotic optical bound states in the continuum. Sci. Rep., 2015, 5: 18301.

[22] Y. Wang, J. Song, L. Dong, M. Lu. Optical bound states in slotted high-contrast gratings. J. Opt. Soc. Am. B, 2016, 33: 2472-2479.

[23] C. Blanchard, J.-P. Hugonin, C. Sauvan. Fano resonances in photonic crystal slabs near optical bound states in the continuum. Phys. Rev. B, 2016, 94: 155303.

[24] D. A. Bykov, E. A. Bezus, L. L. Doskolovich. Coupled-wave formalism for bound states in the continuum in guided-mode resonant gratings. Phys. Rev. A, 2019, 99: 063805.

[25] E. N. Bulgakov, A. F. Sadreev. Bloch bound states in the radiation continuum in a periodic array of dielectric rods. Phys. Rev. A, 2014, 90: 053801.

[26] J. M. Foley, S. M. Young, J. D. Phillips. Symmetry-protected mode coupling near normal incidence for narrow-band transmission filtering in a dielectric grating. Phys. Rev. B, 2014, 89: 165111.

[27] J. M. Foley, J. D. Phillips. Normal incidence narrowband transmission filtering capabilities using symmetry-protected modes of a subwavelength, dielectric grating. Opt. Lett., 2015, 40: 2637-2640.

[28] E. N. Bulgakov, A. F. Sadreev. Bound states in the continuum in photonic waveguides inspired by defects. Phys. Rev. B, 2008, 78: 075105.

[29] Y. H. Ko, R. Magnusson. Flat-top bandpass filters enabled by cascaded resonant gratings. Opt. Lett., 2016, 41: 4704-4707.

[30] E. Silberstein, P. Lalanne, J.-P. Hugonin, Q. Cao. Use of grating theories in integrated optics. J. Opt. Soc. Am. A, 2001, 18: 2865-2875.

[31] J. P. Hugonin, P. Lalanne. Perfectly matched layers as nonlinear coordinate transforms: a generalized formalization. J. Opt. Soc. Am. A, 2005, 22: 1844-1849.

[32] L. Li. Formulation and comparison of two recursive matrix algorithms for modeling layered diffraction gratings. J. Opt. Soc. Am. A, 1996, 13: 1024-1035.

[33] N. A. Gippius, S. G. Tikhodeev, T. Ishihara. Optical properties of photonic crystal slabs with an asymmetrical unit cell. Phys. Rev. B, 2005, 72: 045138.

[34] D. A. Bykov, L. L. Doskolovich, N. V. Golovastikov, V. A. Soifer. Time-domain differentiation of optical pulses in reflection and in transmission using the same resonant grating. J. Opt., 2013, 15: 105703.

[35] N. V. Golovastikov, D. A. Bykov, L. L. Doskolovich. Temporal differentiation and integration of 3D optical pulses using phase-shifted Bragg gratings. Comput. Opt., 2017, 41: 13-21.

[36] H.-C. Liu, A. Yariv. Synthesis of high-order bandpass filters based on coupled-resonator optical waveguides (CROWs). Opt. Express, 2011, 19: 17653-17668.

[37] V. Liu, M. Povinelli, S. Fan. Resonance-enhanced optical forces between coupled photonic crystal slabs. Opt. Express, 2009, 17: 21897-21909.

Leonid L. Doskolovich, Evgeni A. Bezus, Dmitry A. Bykov. Integrated flat-top reflection filters operating near bound states in the continuum[J]. Photonics Research, 2019, 7(11): 11001314.

Integrated flat-top reflection filters operating near bound states in the continuum Download： 507次

关于本站 Cookie 的使用提示

全站搜索

Integrated flat-top reflection filters operating near bound states in the continuum Download： 507次

相关论文

相关资讯

关于本站 Cookie 的使用提示

全站搜索