Abstract
In this work, the diffraction of a Gaussian beam on a volume phase grating was researched theoretically and numerically. The proposed method is based on rigorous coupled-wave analysis (RCWA) and Fourier transform. The Gaussian beam is decomposed into plane waves using the Fourier transform. The number of plane waves is determined using the sampling theorem. The complex reflected and transmitted amplitudes are calculated for each RCWA plane wave. The distribution of the fields along the grating for the reflected and transmitted waves is determined using inverse Fourier transform. The powers of the reflected and transmitted waves are determined based on these distributions. Our method shows that the energy conservation law is satisfied for the phase grating. That is, the power of the incident Gaussian beam is equal to the sum of the powers of the reflected and transmitted beams. It is demonstration of our approach correctness. The numerous studies have shown that the spatial shapes of the reflected and transmitted beams differ from the Gaussian beam under resonance. In additional, the waveguide mode appears also in the grating. The spatial forms of the reflected and transmitted beams are Gaussian in the absence of resonance. It was found that the width of the resonance curves is wider for the Gaussian beam than for the plane wave. However, the spectral and angular sensitivities are the same as for the plane wave. The resonant wavelengths are slightly different for the plane wave and the Gaussian beam. Numerical calculations for four refractive index modulation coefficients of the grating medium were carried out by the proposed method. The widths of the resonance curves decrease with the increasing in the refractive index modulation. Moreover, the reflection coefficient also increases.
Highlights
Sensors for measuring the change in the refractive index, mainly of liquids, have been intensively studied
In work [13], sensitivity of the dielectric grating on the dielectric substrate, the metal grating on the metal substrate, and the prismatic structure have been analyzed for various types of sensors
It was found that the resonant wavelength is equal to the resonant wavelength when the plane wave is incident on the grating
Summary
Sensors for measuring the change in the refractive index, mainly of liquids, have been intensively studied. The grating is irradiated with the limited beam over the cross section in experimental studies It led to a significant decrease in the reflection coefficient and an expansion of the resonant response at the slight modulation of the grating medium refractive index [3,10]. Wedge thickness at any distance from the wedge and yields as a boundary case the the development fringes at plane-wave illumination.of the method for analysis of the limited cross-section beam diffraction by the grating,ofwhich would for be based onofthe numerical. The development the method analysis thewell-proven limited cross-section method, for example, RCWA, is quite important It is especially for periodic structures beam diffraction by the grating, which would be based on the well-proven numericalin which waveguide resonances occur low modulation of the refractive index.
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