The powders of Ca_1–2xBi_2xMo_1–xGe_xO₄ solid solutions weresynthesized by the conventional solid state method and investigated by X–ray powder diffraction and Raman spectroscopy. The Ca_1–2xBi_2xMo_1–xGe_xO₄ compositions crystallize in scheelite structure (sp. gr. I4₁/a) at 0 <x < 0.4, but traces of bismuth germanates are detected by scanning electron microscopy. The x = 0.5 composition contains several phases with BiVO₄- type structures. Raman spectroscopy detected the deformation of [BO₄]^2– polyhedra and changes in B–O bond length (B = Mo, Ge). The energy gaps were calculated from the diffuse scattering spectra by the Kubelka-Munk method. Energy gap (E_g) values decrease with x from 3.29 eV to 2.91 eV, probably due to 6s² electrons of bismuth in the valence band and changes of the conductivity band by electrons of germanium. Such values of E_g can provide photocatalytical activity of powders under UV and visible light. The electrodynamic parameters of the ceramic sample of Ca_1–2xBi_2xMo_1–xGe_xO₄ were measured by the transmission line method. The average permittivity increases with x from ~10 to ~18 which correlates with theoretical ε, V_mol and total polarizability of samples. An increase in the concentration of bismuth and germanium leads to the additional resonant peaks in the spectra of ε, S₁₁ and S₂₁. These resonant peaks can be probably caused by the appearance of irregular structural domains of Bi atoms or induced by the increased size of grains in the ceramic samples.

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