New Horizons for Temperature Sensing and Bioimaging Using Er3+‐Doped Core@Shell Nanoparticles and Effects of H2O and D2O Solvents on Their Spectroscopic Properties

Lanthanide‐doped nanoparticles (NPs) exhibit temperature‐dependent luminescence, enabling the design of luminescent nanothermometers for industrial and medical applications. This research demonstrates the temperature‐sensing properties of NaYF4:7.5%Er3+@NaYF4 and NaErF4@NaYF4 NPs, which have a hexag...

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Published in:Advanced optical materials 2025-01, Vol.13 (2), p.n/a
Main Authors: Ryszczyńska, Sylwia, Soler‐Carracedo, Kevin, Ekner‐Grzyb, Anna, Jurga, Natalia, Ćwierzona, Maciej, Piątkowski, Dawid, Grzyb, Tomasz
Format: Article
Language:English
Subjects:
Absorption spectra
Banded structure
bioimaging
Biological properties
Blue shift
colloids
Core-shell structure
Emission analysis
Emission spectra
Emission spectroscopy
Erbium
Excitation spectra
Fluorides
lanthanide ions
luminescence
Medical imaging
Medical research
Nanoparticles
nanothermometry
Sodium compounds
Solvents
Temperature dependence
upconversion
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container_title Advanced optical materials
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creator Ryszczyńska, Sylwia
Soler‐Carracedo, Kevin
Ekner‐Grzyb, Anna
Jurga, Natalia
Ćwierzona, Maciej
Piątkowski, Dawid
Grzyb, Tomasz
description Lanthanide‐doped nanoparticles (NPs) exhibit temperature‐dependent luminescence, enabling the design of luminescent nanothermometers for industrial and medical applications. This research demonstrates the temperature‐sensing properties of NaYF4:7.5%Er3+@NaYF4 and NaErF4@NaYF4 NPs, which have a hexagonal shape and average size of 17 nm. Their core@shell structure is confirmed using high‐resolution transmission electron microscopy, and they exhibit intense upconversion (UC) emission under 1532 nm excitation in H2O and D2O colloids. The recorded spectra show Er3+ emission bands with varying intensity ratios depending on the Er3+ concentration, chosen solvent, and temperature. The spectroscopic properties of the studied NPs allow for their excitation and observation of emission within biological windows, which makes them useful for bio‐related applications. The emission of prepared NPs is analyzed as a function of temperature from 298 up to 358/363 K in H2O and D2O. The ratios for thermally‐coupled levels  and non‐TCLs and their relative sensitivities are studied. For the high dopant concentration sample in water, the O─H vibrations and blue shift in the absorption spectrum lead to a record relative sensitivity of 2.50% K−1 (at 363 K) for the 2H11/2/4I11/2 ratio. The use of synthesized NPs for bioimaging under 1550 nm excitation is also demonstrated to observe their accumulation in the guts of Daphnia magna. This study presents the synthesis and characterization of Er3+‐doped core@shell NaYF4:7.5%Er3+@NaYF4 and NaErF4@NaYF4 nanoparticles, highlighting their upconversion (UC) properties in H2O and D2O. The work explores the effects of these solvents on spectroscopic behavior, emphasizing applications in temperature sensing and bioimaging. The study also showcases the potential of these nanoparticles for biological imaging under 1550 nm excitation.
doi_str_mv 10.1002/adom.202402053
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subjects Absorption spectra
Banded structure
bioimaging
Biological properties
Blue shift
colloids
Core-shell structure
Emission analysis
Emission spectra
Emission spectroscopy
Erbium
Excitation spectra
Fluorides
lanthanide ions
luminescence
Medical imaging
Medical research
Nanoparticles
nanothermometry
Sodium compounds
Solvents
Temperature dependence
upconversion
title New Horizons for Temperature Sensing and Bioimaging Using Er3+‐Doped Core@Shell Nanoparticles and Effects of H2O and D2O Solvents on Their Spectroscopic Properties
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