Sensitized photon avalanche nanothermometry in Pr3+ and Yb3+ co-doped NaYF4 colloidal nanoparticles

Photon avalanche (PA) is a highly nonlinear luminescence phenomenon that occurs in lanthanide doped materials. PA exhibits a very steep power law relationship between luminescence intensity and the optical pump power. Due to the mechanism of PA emission, even weak perturbations to the energy looping and energy distribution within excited levels of lanthanide emitters are expected to significantly modify luminescent properties. Therefore, in this work, we experimentally study the impact of temperature (from - 175 to 175 ?, with 25 ? steps) on the sensitized PA emission in NaYF4 nanoparticles co-doped with 15% of Yb3+ and 0.5% of Pr3+ ions under 852 nm pumping wavelength. Significant variations of the PA nonlinearity (S = 4.5-9), PA gain (from 50 up to 175), and PA threshold (from 100 up to 700 kW/cm(2)) were observed under temperature rise from - 175 to 175 ?, respectively. The relative temperature sensitivities based on luminescence intensity changes were larger than 1.5% ?(-1) in the whole temperature range, reaching the maximal value of 7.5% ?(-1) at 0 ?. Moreover, a new thermometric parameter was proposed, namely, the PA pump power threshold, which exhibited over 0.5% ?(-1) relative sensitivities in the same wide temperature range. Owing to PA properties, the temperature sensitivity range and the corresponding relative sensitivities may be intentionally tuned by selecting the appropriate pump intensity in respect to the power dependence relationship. These studies not only provide a better understanding of fundamental processes and susceptibility of the sensitized photon avalanche emission to temperature variation, but also show the possibility of using PA materials as sensitive (nano)thermometers.

Automated summary

This research investigates the effect of temperature on sensitized photon avalanche (PA) emission in Yb3+ and Pr3+ co-doped NaYF4 nanoparticles. The results show significant variations in PA nonlinearity, gain, and threshold under temperature changes. Moreover, a new thermometric parameter, PA pump power threshold, with high relative sensitivities, is proposed.