Anomalous thermal activation of green upconversion luminescence in Yb/Er/ZnGdO self-assembled microflowers for high-sensitivity temperature detection

Non-contact optical temperature detection has shown a great promise in biological systems and microfluidics because of its outstanding spatial resolution, superior accuracy, and non-invasive nature. However, the thermal quenching of photoluminescence significantly hinders the practical applications of optical temperature probes. Herein, we report thermally enhanced green upconversion luminescence in Yb/Er/ZnGdO microflowers by a defect-assisted thermal distribution mechanism. A 1.6-fold enhancement in green emission was demonstrated as the temperature increased from 298 K to 558 K. Experimental results and dynamic analysis demonstrated that this behavior of thermally activating green upconversion luminescence originates from the emission loss compensation, which is attributed to thermally-induced energy transfer from defect levels to the green emitting level. In addition, the Yb/Er/ZnGdO microflowers can act as self-referenced radiometric optical thermometers. The ultrahigh absolute sensitivity of 1.61% K-1 and an excellent relative sensitivity of 15.5% K-1 based on the 4F9/2/2H11/2(2) level pair were synchronously achieved at room temperature. These findings provide a novel strategy for surmounting the thermal quenching luminescence, thereby greatly promoting the application of non-contact sensitive radiometric thermometers. A new strategy for thermally activating green upconversion luminescence for high-sensitivity temperature detection in Yb/Er/ZnGdO microflowers.

Automated summary

Non-contact optical temperature detection has great potential in biological systems and microfluidics due to its superior spatial resolution, accuracy, and non-invasive nature. However, the thermal quenching of photoluminescence hinders its practical applications. In this study, a thermally enhanced green upconversion luminescence in Yb/Er/ZnGdO microflowers was achieved through a defect-assisted thermal distribution mechanism. Additionally, the Yb/Er/ZnGdO microflowers acted as self-referenced radiometric optical thermometers, demonstrating high sensitivity temperature detection. These findings provide a novel strategy for overcoming thermal quenching luminescence and promoting the application of non-contact sensitive radiometric thermometers.