Investigation on the photoluminescence and thermoluminescence of BaGa2O4:Bi3+ at extremely low temperatures

Most of the long persistent luminescence (LPL) materials are investigated at room temperature or higher temperatures. However, LPL materials have promising applications in extremely low-temperature conditions. Here, we report a phosphor, namely BaGa2O4:Bi3+, with LPL that can act as a biological-temperature indicator and thermometer at extremely low temperatures. The traps were investigated in detail with the lowest and highest trap densities of 2.39 x 10(6) and 7.23 x 10(7), respectively. The trap distribution ranges from 150 to 750 K in the thermoluminescence (TL) spectrum with corresponding trap depths ranging from 0.310 to 0.716 eV. The TL spectra show that the distribution of the carriers stored in the traps to two emission centers changes with the temperature rising. The low-temperature steady-state photoluminescence (PL) was also investigated. Since the CIE colour coordinates are almost unchanged and the integrated emission intensity at 300 K was still maintained at 88.2% of 7 K, the phosphor presents a stable colour and intensity output. By decomposing the PL spectra at different temperatures, we noticed that one of the deconvoluted full width at half-maximum (FWHM) bands is temperature-sensitive; the thermometer-related parameters were calculated with the maximum values of S-a and S-r to be 0.163 and 0.108%, respectively. Our concept of investigation may promote the follow-up exploration of LPL phosphors under extreme conditions.

Automated summary

BaGa2O4:Bi3+ phosphor exhibits long persistent luminescence at extremely low temperatures, serving as a biological temperature indicator and thermometer. Trap densities, distribution ranges, and steady-state photoluminescence characteristics were extensively investigated in the study. Our findings may contribute to further exploration of LPL phosphors under extreme conditions.