Cr3+-Doped InTaO4 phosphor for multi-mode temperature sensing with high sensitivity in a physiological temperature range

With the increasing demand for non-contact temperature sensing, the development of an optical thermometer with excellent performance is more and more compelling. A Cr3+-doped InTaO4 phosphor was prepared for the implementation of multi-mode high-sensitivity optical temperature sensing. Its temperature-dependent fluorescence intensity and fluorescence lifetime in the temperature range from 240 to 420 K were investigated in detail for achieving two different temperature sensing modes. At 347 K, the optimal relative temperature sensitivities are 2.50% K-1 for the fluorescence intensity mode and 2.27% K-1 for the fluorescence lifetime mode, respectively. Moreover, due to the rapid decrease of the fluorescence lifetime of Cr3+, another temperature sensing scheme based on a time-resolved technique was also presented. Here, the fluorescence intensities of Cr3+ in two different time windows during its decay process were captured with an intensified charge-coupled device (ICCD), and the temperature dependence of the ratio of fluorescence intensities in these two-time windows was calculated and calibrated. An optimal relative sensitivity of 5.03% K-1 at 388 K was achieved in this scheme with a temperature resolution of about 0.3 K. Combined with fluorescence microscopy and the use of the ICCD, the temperature imaging of an operating printed circuit board with high spatial resolution was demonstrated by employing the temperature sensing scheme based on the time-resolved technique. The above results reveal that the InTaO4:Cr3+ phosphor is very promising for applications in multi-mode high-sensitivity optical thermometry and temperature imaging.

Automated summary

With the increasing demand for non-contact temperature sensing, the development of an excellent optical thermometer has become more compelling. In this study, a Cr3+-doped InTaO4 phosphor was prepared and investigated for its temperature-dependent fluorescence intensity and fluorescence lifetime, achieving high-sensitivity temperature sensing in two different modes. Additionally, a time-resolved technique was also presented, which showed improved temperature sensitivity and resolution. The results demonstrate the promising potential of InTaO4:Cr3+ phosphor in multi-mode high-sensitivity optical thermometry and temperature imaging.