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探索镧系掺杂氟氧化物材料用于亮绿色上转换的潜力及其在温度传感和药物递送方面的广阔应用前景。

Exploring the potential of lanthanide-doped oxyfluoride materials for bright green upconversion and their promising applications towards temperature sensing and drug delivery.

作者信息

Mohanty Sonali, Lederer Mirijam, Premcheska Simona, Rijckaert Hannes, De Buysser Klaartje, Bruneel Els, Skirtach Andre, Van Hecke Kristof, Kaczmarek Anna M

机构信息

NanoSensing Group, Department of Chemistry, Ghent University Krijgslaan 281-S3 9000 Ghent Belgium

XStruct, Department of Chemistry, Ghent University Krijgslaan 281-S3 9000 Ghent Belgium.

出版信息

J Mater Chem C Mater. 2024 Jun 29;12(31):11785-11802. doi: 10.1039/d4tc01740d. eCollection 2024 Aug 8.

DOI:10.1039/d4tc01740d
PMID:39132257
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11308806/
Abstract

The most efficient upconversion (UC) materials reported to date are based on fluoride hosts with low phonon energies, which reduce the amount of nonradiative transitions. In particular, NaYF doped with Yb and Er at appropriate ratios is known as one of the most efficient UC phosphors. However, its low thermal stability limits its use for certain applications. On the other hand, oxide hosts exhibit better thermal stability, yet they have higher phonon energies and are thus prone to lower UC efficiencies. As a result, developing host nanomaterials that combine the robustness of oxides with the high upconversion efficiencies of fluorides remains an intriguing prospect. Herein, we demonstrate the formation of ytrrium doped oxyfluoride (YOF:Yb,Er) particles, which are prepared by growing a NaYF:Yb,Er layer around SiO spherical particles and consecutively applying a high-temperature annealing step followed by the removal of SiO template. Our interest lies in employing these materials as Boltzmann type physiological range luminescence thermometers, but their weak green emission is a drawback. To overcome this issue, and engineer materials suitable for Boltzmann type thermometry, we have studied the effect of introducing different metal ion co-dopants (Gd, Li or Mn) into the YOF:Yb,Er particles, focusing on the overall emission intensity, as well as the green to red ratio, upon 975 nm laser excitation. These materials are explored for their use as ratiometric thermometers, and further also as drug carriers, including their simultaneous use for these two applications. The investigation also includes examining their level of toxicity towards specific human cells - normal human dermal fibroblasts (NHDFs) - to evaluate their potential use for biological applications.

摘要

迄今为止报道的最有效的上转换(UC)材料基于声子能量低的氟化物基质,这减少了非辐射跃迁的数量。特别是,以适当比例掺杂Yb和Er的NaYF被认为是最有效的UC荧光粉之一。然而,其低热稳定性限制了其在某些应用中的使用。另一方面,氧化物基质表现出更好的热稳定性,但它们具有更高的声子能量,因此UC效率较低。因此,开发结合氧化物的稳健性和氟化物的高上转换效率的基质纳米材料仍然是一个有趣的前景。在此,我们展示了钇掺杂氟氧化物(YOF:Yb,Er)颗粒的形成,这些颗粒是通过在SiO球形颗粒周围生长一层NaYF:Yb,Er并连续进行高温退火步骤,然后去除SiO模板而制备的。我们的兴趣在于将这些材料用作玻尔兹曼型生理范围发光温度计,但它们微弱的绿色发射是一个缺点。为了克服这个问题并设计适用于玻尔兹曼型测温的材料,我们研究了将不同的金属离子共掺杂剂(Gd、Li或Mn)引入YOF:Yb,Er颗粒的效果,重点关注975 nm激光激发下的整体发射强度以及绿色与红色的比率。探索了这些材料用作比率温度计的用途,还进一步用作药物载体,包括同时用于这两种应用。该研究还包括检查它们对特定人类细胞——正常人皮肤成纤维细胞(NHDFs)的毒性水平,以评估它们在生物应用中的潜在用途。

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