Designing a dual-wavelength excitation Eu3+/Mn4+co-doped phosphors for high-sensitivity luminescence thermometry

Luminescence thermometry has been widely concerned by researchers due to its quick response, high spatial resolution, and remote measurement. However, low sensitivity is still an existing problem and affects its development. Herein, the luminescence thermometer with high sensitivity taking advantage of the distinguished thermal response between Eu3+ and Mn4+ is designed. Excitedly, Eu3+ exhibits an anti-thermal quenching behavior under 310 nm excitation and a slight thermal quenching behavior under 393 nm excitation due to the energy transfer of host -> Eu3+, while Mn4+ presents a strong thermal quenching behavior. Moreover, the energy transfer of Eu3+-> Mn4+ (lambda ex = 310 nm and lambda ex = 393 nm) can also be observed for the Ca2Sb2O7: Eu3+, Mn4+ phosphors during the heating process. On the basis of the diverse thermal quenching behavior of Eu3+ and Mn4+, the thermometric performances are investigated by utilizing the fluorescence intensity ratio (FIR) of Eu3+(5D0 -> 7F2)/Mn4+(2Eg -> 4A2g) under a dual-wavelength excitation. The maximum relative sensitivities of the designed phosphors are determined to be 4.072% K-1 at 305 K under 310 nm and 3.072% K-1 at 351 K under 393 nm excitation. It's worth noting that the thermometric characteristic can be modified by various excitation wavelengths. Hence, the developed Ca2Sb2O7: Eu3+, Mn4+ phosphors have great potential in the field of lumi-nescence thermometry and provide an effective strategy for designing high-sensitivity dual-wavelength excita-tion optical thermometers.

Automated summary

In this study, a luminescence thermometer with high sensitivity was designed by taking advantage of the distinguished thermal response between Eu3+ and Mn4+. The thermometric performances were investigated using the fluorescence intensity ratio (FIR) of Eu3+(5D0 -> 7F2)/Mn4+(2Eg -> 4A2g) under dual-wavelength excitation, and the maximum relative sensitivities were determined to be 4.072% K-1 and 3.072% K-1. This research provides an effective strategy for designing high-sensitivity dual-wavelength excitation optical thermometers and has great potential in the field of luminescence thermometry.