Ximendes Erving C, Pereira Alexsandro F, Rocha Uéslen, Silva Wagner F, Jaque Daniel, Jacinto Carlos
Group of Nano-Photonics and Imaging, Instituto de Física, Universidade Federal de Alagoas, 57072-900, Maceió-AL, Brazil.
Nanoscale. 2019 May 9;11(18):8864-8869. doi: 10.1039/c9nr00082h.
The use and applications of infrared emitting rare-earth luminescent nanoparticles as nanothermometers have attracted a great deal of attention during the last few years. Researchers have regarded rare-earth doped luminescent nanoparticles as appealing systems due to their reliability, sensitivity and versatility for minimally invasive thermal sensing in nanomedicine. The challenge of developing nanothermometers operating over 1000 nm with outstanding brightness and enhanced sensitivity is being constantly addressed. In this sense, this work explores the potential of Tm3+ emissions at around 1.23 and 1.47 μm, under excitation at 690 nm, for ratiometric thermometry in Tm3+ doped LaF3 nanoparticles. The temperature dependence of the 1.23 μm emission band, which cannot be observed in systems such as NaNbO3:Tm, was demonstrated to be very effective and presented a relative thermal sensitivity as high as 1.9% °C-1. The physical mechanisms behind the strong thermal dependences were explained in terms of multiphonon decays and cross-relaxations. As a proof of concept, the nanothermometers presented were capable of accessing the basic properties of tissues in an ex vivo experiment using thermal relaxation dynamics.
在过去几年中,红外发射稀土发光纳米颗粒作为纳米温度计的用途及应用已引起了广泛关注。由于稀土掺杂发光纳米颗粒在纳米医学中进行微创热传感时具有可靠性、灵敏度和多功能性,研究人员将其视为有吸引力的体系。开发在1000nm以上具有出色亮度和更高灵敏度的纳米温度计这一挑战一直受到关注。从这个意义上讲,这项工作探索了在690nm激发下,Tm3+掺杂的LaF3纳米颗粒中,1.23μm和1.47μm附近的Tm3+发射用于比率测温的潜力。在诸如NaNbO3:Tm等体系中无法观察到的1.23μm发射带的温度依赖性被证明非常有效,其相对热灵敏度高达1.9%℃-1。从多声子衰变和交叉弛豫的角度解释了强热依赖性背后的物理机制。作为概念验证,所展示的纳米温度计能够在离体实验中利用热弛豫动力学获取组织的基本特性。
