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Abstract
The characteristics of electromagnetic wave reflection and transmission by multilayered structures consisting of a pair of left-handed material (LHM) and superlattices (LANS) slabs inserted between two semi-infinite dielectric media are investigated for photovoltaic and solar energy applications. Maxwell’s equations are used to determine the electric and magnetic fields of the perpendicular polarized wave incident at each layer. Snell’s law is applied and the boundary conditions are imposed at each layer interface to calculate the reflected and transmitted coefficients of the structure. The reflected, transmitted powers are determined using these coefficients by a recursive method. The reflected and transmitted powers are computed in both visible and microwave spectral band with the appropriate LHM for each band and appropriate location of LANS in the structure. They are illustrated as a function of the incident wavelength, angle of incidence, magnetic fraction of LANS and thickness of the slabs with the emphasis on the appropriate refractive indices. I found that, zero reflectance and maximum transmittance of the incident powers are achieved for visible spectral band at a single frequency if LHM and LANS have the same refractive index of opposite signs with the same width and more magnetic material of LANS while the reflected power is zero for less magnetic material of LANS in the microwave spectral band which realizes antireflection coating in this structure.
Highlights
In many applications, reflection is undesirable and causes insertion losses, for example
Since antireflection coating is formed by two slabs of the same thickness and of opposite refractive indices, a pair of lefthanded materials (LHM) and layer thickness and magnetic fraction of (LANS) materials is situated between two semi-infinite dielectric media which are considered right handed materials (RHM) of positive refractive index
The reflected, transmitted power of the structure is calculated as a function of wavelength of the incident waves, angle of incidence, layer thickness and magnetic fraction of LANS
Summary
Reflection is undesirable and causes insertion losses, for example. I investigate the reflection and transmission properties of a superlattices (LANS)-metamaterial (LHM)-dielectric multilayered structure. Since antireflection coating is formed by two slabs of the same thickness and of opposite refractive indices, a pair of LHM and LANS materials is situated between two semi-infinite dielectric media which are considered right handed materials (RHM) of positive refractive index. In the theory the electric and magnetic fields of the incident waves are determined in each region by Maxwell’s equations. 2. Theory ( ) Consider LHM and LANS of electric permittivity and magnetic permeability (εh , μh ) and ε⊥ , μe respectively embedded between two semi-infinite dielectric media of permeability and permittivity as ( μ1, ε1 ) and (μ4 , ε4 ). Fe and Fm are the scaling filling parameters, γ c and γ m are the electric and magnetic dissipation factors
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