SciresolSciresolhttps://indjst.org/author-guidelinesIndian Journal of Science and Technology10.17485/IJST/v13i15.24Study of transmittance spectra for quaternary periodic structure of 1D photonic crystal for s-wave filterSinghVishal Kumarsingh87vishal@gmail.com1SrivastavaSeema2VibhuIsht3Research scholar, Department of Physics, Integral UniversityLucknow, U.P, 226026, 91-945-323-2699IndiaAssociate Professor, Department of Physics, Integral UniversityLucknow, U.P, 226026IndiaAssociate Professor, Department of Physics, Y.D.P.G collegeLakhimpur Kheri, U.P, 262701India13152020Abstract
Objectives: To study the propagation of electromagnetic waves through the four periodic continuous layers with different refractive indices and spectral analysis with normalized frequency with respect to transmittance and dispersion. Methods: By considering the assumptions the theoretical analysis has been done. Methodology has taken from quantum mechanical treatment of an electron in a potential well with boundary conditions. The dispersion relation is taken from Bloach wave concept. The calculation is taken for arbitrary structure of different refractive indices. The electric field has connected with the periodic 1-D layered structure. The electromagnetic wave as form incident wave, the transmitted wave and reflected wave have been derived using the transmission matrix method. Findings: In theoretical analysis, it is found that the transmittance spectra increasing with continuous increase refractive index. The analysis has been done for a s-polarized or transverse electric mode (TE mode) wave. Properties of these crystals are different from the ordinary materials. Applications: It works as s- polarized filter and blocks p-polarized wave. Calculation has taken for TE mode configuration.
With proper application of potential, motion of electron in a dielectric can be controlled. The speed of electron in a circuit has certain limitations. To improve the speed of information, photons can be considered as carrying agents, which travel with the speed of light. It is difficult to control the motion of photons than an electron. The photon is related to the light and light is an electromagnetic wave. The electromagnetic wave has electric as well as the magnetic field. These two different fields are responsible for the interaction with materials. Electric field interacts with material’s atom while the interaction of magnetic field is normally weak 1. Photonic crystals are emerging in the field of Photonics and are used in different areas such as to control the propagation of light, controlling of signals for a specific frequency. Passing information from one place to another is faster through electromagnetic wave than electronic signals in photonic crystals. The idea of ligament model for light has led in the last 40 years in optics and optical technology to a completely new direction that deals with periodically dielectric media and the light propagation busy in it. 2 The novel materials, which have extremely interesting properties, were given the name Photonic Crystal (PC). As crystal is a periodic arrangement of atoms or molecules in space 3, like that photonic crystals are the periodic arrangement of dielectric materials. Its periodicity is of the order of a wavelength. It can be constructed by the periodic arrangement of dielectric-dielectric or dielectric-metal materials. The composition of metal and a dielectric layer is said to be metallodielectric photonic crystals 4. It is found with properties like perfect reflectance, used as anti-reflecting coatings. Refractive index defines the properties of a material and is given in terms of permittivity(ε) and permeability (μ) of the medium asn=εμ. Photonic crystals provide gap, which is photonic band-gap, which controls the propagation of waves. The regular multiplication of a wave inside the crystal provides band-gap. Band-gap is the frequency range for which the propagation of photons is prohibited inside the photonic crystal 5. Photonic crystals have some specific photonic band structures. It has properties like, pass band, stop band and defect states, that is, some frequencies are allowed and some forbidden. Researchers are continuously trying to construct photonic crystals as per specific need. In this process, there are various techniques have been developed to fabricate photonic crystals for the practical application. The laser direct writing method, vertical deposition method and the laser holographic lithography method are used for the fabrication of photonic crystals. Eli Yablonovitch and Sajeev Jhon independently proposed the concept of photonic crystal in 1987 6. The first assumption to control the propagation of light by a one dimensional periodic structure was given by Igor A. et. al. 7. Ho K. M. et. al. proposed the band-gap structure for FCC lattices. The construction of periodic optical dielectric metamaterials that affects the motion of photons is called as photonic crystals. These are macroscopic periodic or non-periodic artificial structures govern by both their cellular architecture and chemical composition with specific properties 8. Metamaterial structure exists negative index dielectric material of refraction. The negative refraction has been experimentally verified by Valanju et al. 9. In the present work, theoretical analysis of the four layer periodic photonic crystal structure has been done. The medium is assumed to be isotropic and lossless. Electromagnetic wave incident on the surface of crystal then reflection, refraction and transmission of waves occurs. Continuously increase in refractive index, angle of refraction should decrease in a regular way. The wave will propagate in a particular direction. Transmittance should increase. The transmittance of the electromagnetic wave propagation has exactly calculated by the transfer matrix method (TMM) 10. This gives an idea that light is guided by the materials. By considering the assumptions the theoretical analysis has done. The results have plotted by the calculations. Methodology has taken from quantum mechanical treatment of an electron in a potential well with boundary conditions 11. The dispersion relation is taken from Bloach wave concept. 12 The analysis has done for a s-polarized or transverse electric mode (TE mode) wave.
Theoretical analysis
Now we are considering a 1D periodic structure in which propagation of an electromagnetic wave from the left to the right side along the positive X-axis direction and the launching medium is homogeneous along incident and transmitted directions.
Periodic layered 1-D structure
The electric field has connected with the periodic 1-D layered structure. The electromagnetic wave as form incident wave, the transmitted wave and reflected wave has been derived using the transmission matrix method. The Maxwell’s equations of electromagnetic wave and interface boundary conditions gives the electric fields. The derivatives of equation show the continuity of the electric field at the interfaces of each 1D layer. By mathemetical calculation, in nth layer structure, the amplitude of the wave related to the transfer matrix as:
An-1Bn-1=m11m12m21m22AnBn
Where m11, m12, m21 and m22 are the elements of transfer matrix. 13. Transfer matrix elements m11, m12, m21 and m22 are :
By the use of equation (11), we get the transmittance of the wave and by the use of equation (8) get the photonic band gap.
Results
Normalized frequency and dispersion relation, n1=1.0,n2=1.50,n3=2.0,n4=2.50,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=45°.
Normalized frequency and dispersion relation, n1=1.25,n2=1.75,n3=2.25,n4=2.75,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=45°.
Normalized frequency and dispersion relation,n1=1.50,n2=2.0,n3=2.50,n4=3.0,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=45°.
By the use of equations (6) and (8), the Figure 2, Figure 3, Figure 4 are plotted for dispersion relation with normalized frequency. It is found that the band-gap appears for some frequencies. Propagation wave in this frequency range is prohibited. The band-gap tunes with change in refractive indices of medium. It has observed that band-gap shifts towards lower frequencies so the propagation of waves for smaller frequencies will be prohibited.
Figures for normalized frequency and transmittance,n1=1.0,n2=1.50,n3=2.0,n4=2.50,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=0°
Figures for normalized frequency and transmittance, n1=1.0,n2=1.50,n3=2.0,n4=2.50,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=30°.
Figures for normalized frequency and transmittance, n1=1.0,n2=1.50,n3=2.0,n4=2.50,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=60°.
Figures for normalized frequency and transmittance, n1=1.0,n2=1.50,n3=2.0,n4=2.50,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=89°.
Figure 4, Figure 5, Figure 6, Figure 7 show transmittance spectra for variation of angle of incidence and refractive indices. Here observed some peaks at0°, 30°and60°. it means for selected frequency transmittance will be maximum. As the increase in angle of incidence, the peak shifts towards higher frequency so transmittance can obtain for higher frequencies analytically.
Figures for normalized frequency and transmittance, n1=1.25,n2=1.75,n3=2.25,n4=2.75,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=0°.
Figures for normalized frequency and transmittance, n1=1.25,n2=1.75,n3=2.25,n4=2.75,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=30°.
Figures for normalized frequency and transmittance, n1=1.25,n2=1.75,n3=2.25,n4=2.75,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=60°.
Figures for normalized frequency and transmittance, n1=1.25,n2=1.75,n3=2.25,n4=2.75,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=89°.
Figure 8, Figure 9, Figure 10, Figure 11 shows that transmittance has been observed. In Figure 8, Figure 10 do not show a good transmission, here only at a particular frequency the transmission is observed.
Figures for normalized frequency and transmittance,n1=1.50,n2=2.0,n3=2.50,n4=3.0,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=0°.
Figures for normalized frequency and transmittance, n1=1.50,n2=2.0,n3=2.50,n4=3.0,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=30°.
Figures for normalized frequency and transmittance, n1=1.50,n2=2.0,n3=2.50,n4=3.0,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=60° .
Figures for normalized frequency and transmittance, n1=1.50,n2=2.0,n3=2.50,n4=3.0,a1=0.045,b1=0.015,a2=0.030,b2=0.010,θ=89°.
In Figure 12, Figure 13, Figure 14, Figure 15 found a good transmittance but Figure 11 is good only for a particular frequency. Figure 12, Figure 13, Figure 14, Figure 15 are transmittance spectra for a four layer structure. The regions with zero transmittance founded in all. There are some regions that show zero transmittance. In that region perfect reflectance will observe. The propagation wave is prohibited in these regions. It shows the photonic band-gap.
Conclusion
From the results and analysis, it is found that the structure appears with band-gap by the increase in refractive index at different refractive incidences. For some angles with a constant refractive index of materials, transmittance found to be maximum for a particular frequency. These structures can be used for the selection of a specific frequency. The materials lie between the considered refractive indices should show the same behavior as obtained. It is for s-polarized wave so; it works as s-polarized filter and completely stops the p-polarized wave.
Acknowledgement
Authors are thankful to the research and development of integral University, Lucknow for providing the research facilities and manuscript communication number IU/R&D/2020-MCN000811.
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