A Monte Carlo Study of Flux Ratios of Raman Scattered O~VI Features at 6825 \ and 7082 \ in Symbiotic Stars

Abstract

Symbiotic stars are regarded as wide binary systems consisting of a hot white dwarf and a mass losing giant. They exhibit unique spectral features at 6825 \ and 7082 , which are formed via Raman scattering of O6λλ 1032 and 1038 with atomic hydrogen. We adopt a Monte Carlo technique to generate the same number of O6λ1032 and λ1038 line photons and compute the flux ratio F(6825)/F(7082) of these Raman scattered O6 features formed in neutral regions with a simple geometric shape as a function of H1 column density NHI. In cylindrical and spherical neutral regions with the O6 source embedded inside, the flux ratio F(6825)/F(7082) shows an overall decrease from 3 to 1 as NHI increases in the range 1022-24\ cm-2. In the cases of a slab geometry and other geometries with the O6 source outside the H1 region, Rayleigh escape operates to lower the flux ratio considerably. For moderate values of NHI 1023\ cm-2 the flux ratio behaves in a complicated way to exhibit a broad bump with a peak value of 3.5 in the case of a sphere geometry. We find that the ratio of Raman conversion efficiencies of O6λλ1032, 1038 ranges from 0.8 to 3.5. Our high resolution spectra of 'D' type HM~Sge and 'S' type AG~Dra obtained with the Canada-France-Hawaii-Telescope show that the flux ratio F(6825)/F(7082) of AG~Dra is significantly smaller than that of HM~Sge, implying that 'S' type symbiotics are characterized by higher NHI than 'D' type symbiotics.