Boltzmann Thermometry at Cryogenic Temperatures Exploiting Stark Sublevels in Er3+/Yb3+-Codoped Yttrium Oxide Nanoparticles

Abstract

The development of reliable luminescent nanothermometers for cryogenic applications is essential for advancing quantum technologies, superconducting systems, and other fields that require precise, high-spatial-resolution temperature monitoring. Lanthanide-doped systems are vastly employed to this purpose, and typically perform optimally at or above room temperature when manifold-to-manifold transitions are used. In this work we exploit individual Stark sublevels to demonstrate an optical thermometer based on Er3+/Yb3+ codoped yttria (Y2O3) nanoparticles that operates effectively across the temperature range from 25 K to 175 K. This is achieved due to the pronounced crystal field environment of the the Y2O3 host matrix, leading to well-separated Stark lines in the luminescence spectrum of the Er3+ ions. By applying the Luminescence Intensity Ratio (LIR) method to transitions originating from two Stark components of the 4S3/2 manifold of the Er3+ ions, we achieve thermal sensitivities up to 1.25 % K-1 at 100 K and temperature resolutions reaching 0.2 K. Our results further experimentally confirm recently published theoretical predictions, demonstrating that thermometric performance is not directly dependent on the average (barycenter) difference of the involved electronic energy levels when using individual Stark transitions to evaluate the LIR. The proposed procedure gives an energy gap calibration that matches the one determined by sample spectroscopy for non-overlapping lines in the luminescence spectrum. These insights provide a robust foundation for the design of high-performance cryogenic thermometers based on rare-earth-doped materials.