Amorphous oxide semiconductors (AOSs) have been extensively studied because of their high electron mobility. Conventionally, AOSs are alloys of metal oxides of which conduction band minima (CBM) consist of metal s-orbitals. Recently, very high mobility over 100 cm²V^–1s^–1 was reported in a mixed-anion compound, ZnO_xN_y. Although the origin of high mobility has not been fully understood, one hypothesis is that CBM of ZnO_xN_y is spatially more homogeneous than conventional AOSs because it is composed of only Zn 4s-orbital. This hypothesis suggests high mobility in other amorphous mixed-anion compounds such as oxyfluoride and oxysulfide. In this study, we fabricated amorphous ZnO_xS_y thin films and investigated their electrical transport properties.
We tried alternate deposition of ZnS and ZnO targets under vacuum, and succeeded in obtaining ZnO_xS_y over the whole anion range. We found that while the end members, ZnS and ZnO were crystalized, their alloys became amorphous in a wide range under low laser fluence conditions. The resistivity of the amorphous ZnO_xS_y films increased with increase of S content or decrease of laser fluence. The films fabricated with higher laser fluence showed larger electron concentration N_e probably due to introduction of oxygen vacancies. Hall mobility μ_H vs Ne plot showed that the μ_H of the amorphous ZnO_xS_y films reached to 10-15 cm²V^–1s^–1. These results indicate that amorphous ZnO_xS_y is a promising amorphous semiconductor.