Design of white-emitting optical temperature sensor based on energy transfer in a Bi3+, Eu3+ and Tb3+ doped YBO3 crystal

Phosphors for remote optical determination have gained great attention for their promising applications, due to their advantageous rapid and noninvasive detection compared to traditional thermometers. In this work, a novel white-emitting optical temperature sensor based on energy transfer in a Bi3+, Eu3+ and Tb3+ doped YBO3 crystal was designed. By making full use of the crystal structure information and an energy transfer strategy, we obtained a series of wide range color tunable phosphors including one with white emission, which makes it a candidate to replace phosphors for white light emitting diodes (WLEDs). The temperature sensitive energy transfer from the host and Bi3+ to Eu3+ and Tb3+ has been demonstrated by analyzing the spectra from phosphors with different concentrations of the doping ions, in which Bi3+ acts as both the emission center and sensitizer. By investigating the temperature-dependent emission of the white light emitting phosphor YBO3:0.04Bi(3+),0.003Eu(3+),0.008Tb(3+), the absolute sensitivity value (S-a) and relative sensitivity value (S-r) were calculated in different temperature ranges of 200 to 300 K and 298 to 473 K, in which the maximum value of S-r reaches 0.57% K-1 at 398 K. Although the S-r values are not high enough for practical application, our design concept may provide a new perspective for developing novel multifunctional phosphors used as optical temperature sensors and WLED phosphors.

Automated summary

A novel white-emitting optical temperature sensor based on energy transfer in a YBO3 crystal was designed, which offers a series of color tunable phosphors and potential as a replacement for WLED phosphors. The study demonstrates temperature sensitive energy transfer dynamics and calculates sensitivity values, providing a new perspective for developing multifunctional phosphors for optical temperature sensing and WLED applications.