Abstract
In this study, we synthesized a series of Ga(1.98-x)In(x)O(3):0.02Cr(3+) materials with varying x values from 0.0 to 1.0, focusing on their broadband near-infrared emission and photoelectric properties. Interestingly, photocurrent excitation spectra exhibited behavior consistent with the absorption spectra, indicating the promotion of carriers into the band structure by the (4)T(1), and (4)T(2) states of Cr(3+) ions. This association suggests that photocurrent in this material is influenced not only by valence to conduction band transitions but also by transitions involving Cr(3+) dopants. Our investigation of luminescence quenching mechanisms revealed that nonradiative processes were not directly linked to thermally induced relaxation from the excited state (4)T(2) to the ground state (4)A(2), as usually suggested in the literature for this type of material. Instead, we linked it to the thermal ionization of Cr(3+) ions. Unexpectedly, this process is unrelated to the transfer of electrons from Cr(3+) impurities to the conduction band but is associated with the formation of holes in the valence band. This study provided novel evidence of luminescence quenching via the hole-type thermal quenching process in Cr(3+)-doped oxides, suggesting potential applicability to other transition metal ions and host materials. Finally, we demonstrated the dual-purpose nature of Ga(1.98-x)In(x)O(3):0.02Cr(3+) as a practical emitter for NIR-pc-LEDs and effective photocurrent for UV detectors. This versatility underscores these materials' practicality and broad application potential in optoelectronic devices designed for near-infrared and ultraviolet applications.