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Understanding shell coating effects to overcome quenching in single anisotropic upconversion nanoparticles

Yangjian Cai, Ming Lu, Xian Qin, Dayong Jin, Jiajia Zhou

2025Nature Communications11 citationsDOIOpen Access PDF

Abstract

Shell coating is known to suppress luminescence quenching in spherical upconversion nanoparticles. However, the emergence of anisotropic nanoparticles with facet-selective, directional growth complicates the coating process, and the use of traditional active, inert, or polymer coatings on such structures remains largely unexplored. Here, we synthesize a series of nanorods with designed geometries, enabling quantitative spectral analysis at the single-particle level. We observe that directional growth of inert or active shells at the rod tips enhances emission relative to the parent core, with their relative effectiveness governed by power density and shell thickness. Ligand presence—polymer or oleate—quenches upconversion relative to bare nanorods. Although local heating is observed at the single-particle level, it does not affect spectroscopic observations, ligand stability, or data reproducibility. Our findings reveal how directionally grown shells influence the optical properties of upconversion nanorods, providing essential insights for their future applications in bioimaging, sensing, and photonics. Shell coatings reduce luminescence quenching in spherical nanoparticles for upconversion, but anisotropic nanoparticles are less well studied. Here, the authors investigate the effects of coatings on individual nanorods and show that their effectiveness depends on power density and shell types.

Topics & Concepts

Shell (structure)CoatingQuenching (fluorescence)Materials scienceNanoparticlePhoton upconversionNanotechnologyAnisotropyOptoelectronicsPhysicsOpticsComposite materialFluorescenceDopingLuminescence Properties of Advanced MaterialsLuminescence and Fluorescent MaterialsRadiation Detection and Scintillator Technologies