Synthesis and thermometry of NV- nanodiamond α-NaYF4 composite nanostructures

Lars Forberger, R. G. Felsted, Alexander B. Bard, Danika R. Luntz-Martin, A. N. Vamivakas, P. Pauzauskie
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引用次数: 1

Abstract

Negatively charged nitrogen-vacancy (NV-) centers in diamond have a plethora of potential applications in quantum systems, including sensing and computing1-3. Photothermal heating can limit the utility of NV- center nanodiamonds, especially under high laser irradiances4-6. A composite of nanodiamonds with NV- defects and ytterbium-doped cubic sodium yttrium fluoride (Yb:α-NaYF4 or NaYF) could offset the photothermal heating of nanodiamonds by the anti-Stokes fluorescence cooling of Yb3+ ions7. We present a novel preparation method for generating a NV- diamond NaYF composite material based on a hydrothermal synthesis approach. Particle size was determined to be 230 ± 90 nm by SEM, and DLS data show a permanent connection between nanodiamonds and NaYF. Nanodiamonds are observed on the surfaces of NaYF materials. Nanodiamonds may also be incorporated within the body of individual NaYF grains, however the question of whether nanodiamonds are fully incorporated into the host NaYF material remains to be answered. The temperatures of host material and NV- defects are accessed using mean fluorescence wavelength shifts and Debye-Waller factor thermometry respectively. The obtained temperature changes with increasing 1020 nm irradiance show good agreement. Two data sets showed photothermal heating of around 10 and 13 K at 6.3 MW/cm2. Increased particle smoothness and sizes could lead to coolable composite materials.
NV-纳米金刚石α-NaYF4复合纳米结构的合成与测温
金刚石中带负电荷的氮空位(NV-)中心在量子系统中有大量潜在的应用,包括传感和计算1-3。光热加热会限制NV中心纳米金刚石的应用,特别是在高激光辐照度下。含有NV-缺陷的纳米金刚石与掺镱立方氟化钇钠(Yb:α-NaYF4或NaYF)的复合材料可以通过Yb3+离子的反stokes荧光冷却抵消纳米金刚石的光热加热7。提出了一种基于水热合成法制备NV-金刚石NaYF复合材料的新方法。SEM测得纳米金刚石的粒径为230±90 nm, DLS数据显示纳米金刚石与NaYF之间存在永久联系。在NaYF材料表面观察到纳米金刚石。纳米金刚石也可能结合在单个NaYF颗粒的体内,但是纳米金刚石是否完全结合到宿主NaYF材料的问题仍有待回答。利用平均荧光波长位移法和德拜-沃勒因子测温法分别获得了基体材料和NV缺陷的温度。所得温度随1020nm辐照度增加的变化符合较好。两组数据显示,在6.3 MW/cm2下,光热加热约为10和13 K。增加颗粒的平滑度和尺寸可能导致可冷却的复合材料。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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