Litcius/Paper detail

Optical super-resolution nanothermometry via stimulated emission depletion imaging of upconverting nanoparticles

Ziyang Ye, Benjamin Harrington, Andrea D. Pickel

2024Science Advances30 citationsDOIOpen Access PDF

Abstract

From engineering improved device performance to unraveling the breakdown of classical heat transfer laws, far-field optical temperature mapping with nanoscale spatial resolution would benefit diverse areas. However, these attributes are traditionally in opposition because conventional far-field optical temperature mapping techniques are inherently diffraction limited. Optical super-resolution imaging techniques revolutionized biological imaging, but such approaches have yet to be applied to thermometry. Here, we demonstrate a super-resolution nanothermometry technique based on highly doped upconverting nanoparticles (UCNPs) that enable stimulated emission depletion (STED) super-resolution imaging. We identify a ratiometric thermometry signal and maintain imaging resolution better than ~120 nm for the relevant spectral bands. We also form self-assembled UCNP monolayers and multilayers and implement a detection scheme with scan times >0.25 μm 2 /min. We further show that STED nanothermometry reveals a temperature gradient across a joule-heated microstructure that is undetectable with diffraction limited thermometry, indicating the potential of this technique to uncover local temperature variation in wide-ranging practical applications.

Topics & Concepts

STED microscopyMaterials scienceImage resolutionResolution (logic)NanoparticleNanoscopic scaleStimulated emissionNanotechnologyOpticsOptoelectronicsLaserComputer sciencePhysicsArtificial intelligencePhotoacoustic and Ultrasonic ImagingAdvanced Fluorescence Microscopy TechniquesThermal Radiation and Cooling Technologies