Abstract
It is proposed that a macroscopic theory of propagation and scattering of light through random media can be functional for the dye liquid flowing media in the microscopic levels too, with modest approximations. Maxwell’s equation for a random refractive index medium is approximated and solved for the electric field. An analytical expression for the spectral intensity of the field scattered by the refractive index fluctuations inside a medium has been derived which was valid within the first Born approximation. Far field spectral intensity variation of the radiation propagating through the liquid medium is a consequence of variation in correlation function of the refractive index inhomogeneities. The strength of radiation scattered in a particular direction depends on the spatial correlation function of the refractive index fluctuations of the medium. An attempt is made to explain some of the experimentally observed spectral intensity variations, particularly dye emission propagation through liquid flowing medium, in the presence of thermal and flow field.
Highlights
Scattering of light is regarded as an interaction of light with matter, which leads to a change of the direction and/or the length of the incident light wave
It was established that macroscopic theory of propagation and scattering of light through random media can be functional for the dye liquid flowing media in microscopic level, with the modest approximations
Spatial correlation function known for a long time has been correlated with refractive index fluctuations of the flowing dye medium
Summary
Scattering of light is regarded as an interaction of light with matter, which leads to a change of the direction and/or the length of the incident light wave. To the best of our knowledge, no report is available on the spectral intensity variation by the correlation function of the refractive index fluctuation of the microscopic liquid media, dye emission propagation through inhomogeneous liquid gain medium. Analytical expression for the spectral intensity of the radiation scattered in terms of the correlation function of the refractive index of the inhomogeneous medium is derived, starting from Maxwell’s field equation.
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