Adjustable three color optical filters using ferroelectric -dielectric generalized heterostructures photonic crystals
محورهای موضوعی : فصلنامه نانوساختارهای اپتوالکترونیکیbehnam kazempour 1 , fatemeh moslemi 2
1 - Department of physics, Ahar Branch, Islamic Azad University, Ahar, Iran
2 - Department of physics, Azarbaijan Shahid Madani University, Tabriz, Iran
کلید واژه: Photonic Crystal, Band Gap, External Voltage, Three-Color Filter,
چکیده مقاله :
Abstract: The current research is aimed to investigate the alterations of its optical
features of novel adjustable three color narrowband optical filters, which comprise of
blue, green and red light. A narrowband adjustable transmission optical filters according
to dielectric- ferroelectric heterostructures photonic structures are designed using the
transfer-matrix method (TMM). The dependence of the ferroelectric refractive index on
the external applied voltage is considered in our investigations. The transmission spectra
of the designed hetrostructures with the most valuable parameters, like repeat cycle
counts number of PCs, external electric field, and incident angle for both TE and TM
polarizations are numerically investigated. The results show that the transmission peaks
of three color filter shift toward the shorter wavelength by increasing the incident angle
for both polarization. Also, adjustability of the optical features of the proposed
hetrostructures crystals external applied electric field is investigated .Therefore, these
calculated results reveal an innovative idea for designing the tunable trichromatic filter
and display applicationsthis.
[1] K. Sakoda, Optical Properties of Photonic Crystals, Springer-Verlag, Berlin
(2001)(.
[2] J. D. Joannopoulos, R. D. Meade, J. N.Winn, Photonic Crystals: Molding the Flow of Light, Princeton University Press, Princeton, NJ ( 1995).
[3] M. Skorobogatiy, J. Yang, Fundamentals of Photonic Crystal guiding, Cambridge University Press (2009).
[4] B. Xu, G. Zheng, Y. Wu, Narrow band and angle insensitive filter based on one dimensional photonic crystal containing graded index defect, Mod. Phys. Lett.B. 29, 128-136 (2015).
[5] A. H .Aly, S.A. El-Naggar, H.A.Elsayed, Tunability of two dimensional n-doped semiconductor photonic crystals based on the Faraday effect, Optics Express 23, 15038-15046 (2015).
[6] A. Gharaati, H. Azarshab, Characterization of defect modes in one-dimensional ternary metallo-dielectric nanolayered photonic crystal, PIER B 37, 125-141 (2012).
[7] B. Kazempour, K. J-Ghaleamshidih, Use of uniaxial ferroelectric material as a tunable double-optical filter based on polarization converter and splitting in photonic crystal, Optik 168 , 839-846 (2018).
[8] K. Jamshidi- ghaleh and B. Kazempour, Effect of incident angle and polarization on electrically-tunable defect mode in anisotropic photonic crystal, Appl. Opt. 55, 4350-4357 (2016).
[9] N. Taleb, Optical modes in slab waveguides with magneto electric effect, J. Opt. 18, 055607 (2016).
[10] Z. Baraket, J. Zaghdoudi, M. Kanzari , Investigation of the 1D symmetrical linear graded superconductordielectric photonic crystals and its potential
applications as an optimized low temperature sensors, Optical Materials 64 , 147-151 (2017).
[11] S. A. Shaheen, and S. A. Taya, Propagation of p-polarized light in photonic crystal for sensor application, Chinese Journal of Physics. 55, 571-582 (2017).
[12] C.-J. Wu, Z.H. Wang, Properties of defect modes in one dimensional photonic crystals. Prog. electromagn. Res. 103, 169–184 (2010).
[13] K. Jamshidi- Ghaleh, B. Kazemour, and A. Phirouznia, Electrically Tunable Polarization Splitting and Conversion Based on 1DPC Structure with Anisotropic Defect Layer, Superlattices and Microstructures 101, 109-116 (2017).
[14] S. Roshan Entezar, Z. Saleki, A. Madani, Optical properties of a defective one-dimensional photonic crystal containing graphene nanaolayers, Physica B 478, 122-126 (2015).
[15] S. Kumar Awasthi, R. Panda, and L. Shiveshwari, Multichannel tunable filter properties of 1D magnetized ternary plasma photonic crystal in the presence of evanescent wave, Phys. Plasmas 24, 072111 (2017) .
[16] P. N .Li, Y .W.Liu, Multichannel filtering properties of photonic crystals consisting of single-negative materials, Phys. Lett. A 373, 1870-1873 (2009).
[17] A. H. Aly , H. A. Elsayed, Defect mode properties in a one-dimensional photonic crystal, Physica B 407, 120–125 (2012).
[18] M. J. P. Loschialpo, and J. Schelleng, Photonic band gap structure and transmissivity of frequency- dependant metallic-dielectric systems, J. Appl. Phys. 88, 5785-5790 (2000).
[19] Z.S. Wang, L. Wang, Y.G. Wu, L.Y. Chen, X.S. Chen, W. Lu, Multiple channeled phenomena in heterostructures with defects mode , App. Phys. Lett. 84, 1629 (2004).
[20] G. Q. Liang, P. Han, and H. Z. Wang, Narrow frequency and sharp angular defect mode in one-dimensional photonic crystals from a photonic heterostructure, Opt. Lett. 29, 192–194 (2004).
[21] L. Wang, Z.S. Wang, Y.G. Wu, L.Y. Chen, S.W. Wang, X.S. Chen, W. Lu, Enlargement of the nontransmission frequency range of multiple-channeled filters by the use of heterostructures, J. App. Phys. 95, 424 (2004).
[22] K. J. Ghaleh and B. Kazempour, External tunability of optical filter in symmetric one-dimensional photonic crystals containing ferroelectric and ITO material defect, Optik 127 , 10626–10631 (2016).
[23] I. Abdulhalim, Analytic propagation matrix method for linear optics of arbitrary biaxial layered media, J. Opt. A 1, 646 (1999).
[24] P. Yeh, Electromagnetic propagation in birefringent layered media, J. Opt. Soc. Am. 69, 742 (1979).
[25] A. Yariv and P. Yeh, Optical Waves in crystals propagation and control of laser radiation, Wiley and Sons, New York (1983).
[26] B.E. Saleh, M.C. Teich, B.E. Saleh, Fundamentals of Photonics, vol. 22, Wiley, New York (1991).
[27] M. Born and E. Wolf, Principles of Optics, 7th (expanded) ed. Cambridge University (1999).
[28] A. Rashidi, A. Namdar a, R.A. Ghaleh, Absorption behavior in graphene-based one-dimensional photonic crystals containing a x-cut lithium niobate layer, Sup. Micro. 105, 74-80 (2017).
[29] G. Rosenman, P. Urenski, A. Agronin and Y. Rosenwaks, Submicron ferroelectric domain structures tailored by high-voltage scanning probe microscopy, Appl. Phys. Lett. 82, 103 (2003).
[30] M. Molotskii, A. Agronin, P. Urenski, M. Shvebelman, G. Rosenman, Y. Rosenwaks, Ferroelectric domain breakdown, Phys. Rev. Lett. 90 (10), 107601-10760 (2003).