Phase transition facilitated highly sensitive luminescence nanothermometry and thermal imaging

TL;DR

This paper introduces a highly sensitive nanothermometry method using phase transition-induced luminescence changes in europium-doped LiYO2, achieving millikelvin thermal resolution and enabling precise nanoscale temperature imaging.

Contribution

It demonstrates a novel luminescent nanothermometer based on phase transition effects in europium-doped LiYO2, with room temperature operation and high thermal sensitivity.

Findings

Phase transition causes significant luminescence changes.

Size reduction shifts phase transition temperature to room temperature.

Nanothermometer achieves millikelvin thermal resolution.

Abstract

Currently available temperature measurements or imaging at nano-micro scale are limited to fluorescent molecules and luminescent nanocrystals, whose spectral properties respond to temperature variation. The principle of operation of these conventional temperature probes is typically related to temperature induced multiphonon quenching or temperature dependent energy transfers, therefore, above 12%/K sensitivity and high thermal resolution remain a serious challenge. Here we demonstrate a novel class of highly sensitive thermographic phosphors operating in room temperature range with milikelvin thermal resolution, whose temperature readings are reproducible, luminescence is photostable and brightness is not compromised by thermal quenching. Corroborated with phase transition structural characterization and high spatio-temporal temperature imaging, we demonstrated that optically active europium ions are highly and smoothly susceptible to monoclinic to tetragonal phase transition in LiYO2 host, which is evidenced by changed number and the splitting of Stark components as well as by smooth variation of contribution between magnetic and electric dipole transitions. Further, reducing the size of phosphor from bulk to nanocrystalline matrix, shifted the phase transition temperature from 100oC down to room temperature. These findings provide insights into the mechanism underlaying phase transition based luminescence nanothermometry and motivate future research toward new, highly sensitive, high temporal and spatial resolution nano-thermometers aiming at precise studying heat generation or diffusion in numerous biological and technology applications.