Transport Properties of Doped Wide Band Gap Layered Oxychalcogenide Semiconductors Sr₂GaO₃Cu Ch, Sr₂ScO₃Cu Ch, and Sr₂InO₃Cu Ch (Ch = S or Se)

The structural, electrical, and optical properties of a series of six layered oxychalcogenides with the general formula Sr₂ MO₃CuCh, where M = Ga, Sc, or In and Ch = S or Se, have been investigated. From this set, we report the structure and properties of Sr₂GaO₃CuSe for the first time, as well as the full structural details of Sr₂ScO₃CuSe, which have not previously been available. A systematic study of the suitability of all of the Sr₂ MO₃CuCh phases as p-type conductors has been carried out, after doping with both sodium and potassium to a nominal composition of A _0.05Sr_1.95 MO₃CuCh, (A = Na or K), to increase the hole carrier concentration. Density functional theory calculations were used to determine the electronic band structure and predict the transport properties, while optical properties were determined using UV-vis spectroscopy, and structures were confirmed using Rietveld refinement against powder X-ray diffraction data. Room-temperature conductivity measurements were carried out on both pristine samples and doped samples, 18 compositions in total, using four-point probe measurements. We found that the most conductive sample was K_0.05Sr_1.95GaO₃CuSe, with a measured conductivity of 0.46 S cm^-1, collected from a sintered pellet. We have also been able to identify a relationship between the conductivity and the geometry of the copper chalcogenide layer within the Sr₂ MO₃CuCh series of compounds. As this geometry can be controlled through the material composition, the identification of this structure-property relationship highlights a route to the selection and identification of materials with even higher conductivities.