Mn2+离子/二聚体差异化热响应的CaF2纳米探针实现多模式光学测温

doi:10.6023/A25070252

摘要/Abstract

近年来, 基于无机纳米材料的光学测温技术因其高灵敏度、非接触测量和良好的生物相容性等优势, 在生物医学温度传感领域展现出重要应用前景. 本研究通过溶剂热法成功制备了CaF₂:Mn²⁺纳米颗粒, 并系统研究了其温度依赖的光学特性. 实验结果表明: 该纳米颗粒的发光强度、发射峰位置和荧光寿命均表现出显著的温度响应特性. 进一步研究发现: 在近红外第一生物窗口内(650~950 nm), CaF₂:Mn²⁺纳米颗粒呈现出Mn²⁺-Mn²⁺二聚体的特征发射(680~950 nm), 且其热猝灭效应强于Mn²⁺离子的发光. 基于上述实验结果, 建立了基于CaF₂:Mn²⁺纳米颗粒的多模式光学温度传感策略. 其中, Mn²⁺-Mn²⁺二聚体发光强度、发光强度比(Mn²⁺离子/Mn²⁺-Mn²⁺二聚体)和Mn²⁺-Mn²⁺二聚体寿命模式在生理温度内(300~330 K)表现出最佳测温性能, 其相对灵敏度分别为2.82%•K⁻¹ (330 K)、0.79%•K⁻¹ (305 K)和0.65%•K⁻¹ (330 K), 这为生物测温提供了可靠的多模式测量方案. 本研究不仅证实了CaF₂:Mn²⁺纳米颗粒在生物温度传感领域中的应用潜力, 更为开发新型高灵敏度的生物测温探针提供了重要理论参考和实验依据.

关键词: CaF₂:Mn²⁺纳米颗粒, Mn²⁺-Mn²⁺二聚体, 发光强度比, 生物测温, 多模式测温

In recent years, optical thermometry based on inorganic nanomaterials has demonstrated significant application potential in biomedical temperature sensing due to its high sensitivity, non-contact measurement capability, and excellent biocompatibility. Compared with a single temperature sensing mode, the development of a multi-mode optical temperature sensing strategy is expected to significantly improve the accuracy and reliability of temperature detection, which has become an important research direction in this field. In this work, a series of CaF₂:Mn²⁺ nanoparticles with particle size of about 10~20 nm have been successfully prepared through a solvothermal approach. In order to further reveal the structure-activity relationship of CaF₂:Mn²⁺, its structural composition and microscopic morphology were systematically characterized by X-ray diffraction, X-ray photoelectron spectroscopy and transmission electron microscopy. The luminescence properties and temperature-dependent response behavior of CaF₂:Mn²⁺ were explored in detail by spectroscopic analysis. On this basis, the potential application prospects of the material in the field of optical temperature sensing are further discussed. The experimental results demonstrate that the nanoparticles exhibit significant temperature-dependent characteristics in luminescence intensity, emission peak position, and fluorescence lifetime. Further investigation revealed that the CaF₂:Mn²⁺ nanoparticles exhibited characteristic emission from Mn²⁺-Mn²⁺ dimers (680~950 nm) within the first near-infrared biological window (650~950 nm), and showed stronger thermal quenching effects compared to Mn²⁺ ions. Based on these experimental results, we have established a multimodal optical temperature sensing strategy utilizing CaF₂:Mn²⁺ nanoparticles. Among these, the temperature sensing models based on luminescence intensity of the Mn²⁺-Mn²⁺ dimer, the luminescence intensity ratio (Mn²⁺ ions / Mn²⁺-Mn²⁺ dimer), and the lifetime of the Mn²⁺-Mn²⁺ dimer demonstrate optimal temperature sensing performance within the physiological temperature range (300~330 K). Corresponding relative sensitivities are 2.82%•K⁻¹ (330 K), 0.79%•K⁻¹ (305 K), and 0.65%•K⁻¹ (330 K), respectively, providing a reliable multi-mode measurement scheme for biological thermometry. This study not only confirms the application potential of CaF₂:Mn²⁺ nanoparticles in the field of biological temperature sensing, but also provides important theoretical references and experimental basis for the development of novel high-sensitivity biothermometry probes.

Key words: CaF₂:Mn²⁺ nanoparticles, Mn²⁺-Mn²⁺ dimers, luminescence intensity ratio, biothermometry, multimodal thermometry

引用此文

刘文素, 江莎, 王渝童, 谢林林, 张登翔, 谭力伟, 汪永杰. Mn²⁺离子/二聚体差异化热响应的CaF₂纳米探针实现多模式光学测温[J]. 化学学报, 2025, 83(12): 1551-1560.

Wensu Liu, Sha Jiang, Yutong Wang, Linlin Xie, Dengxiang Zhang, Liwei Tan, Yongjie Wang. CaF₂ Nanoprobes with Mn²⁺ Ions/Dimers Exhibiting Differential Thermal Responses for Multimodal Optical Thermometry[J]. Acta Chimica Sinica, 2025, 83(12): 1551-1560.

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图/表 6

图1. (a) CaF2晶体结构; (b) CaF2:x%Mn2+ (x=0, 4, 5, 6, 7, 8)样品的XRD图及在27.5°~30°的局部放大图; (c) CaF2:6%Mn2+纳米颗粒的XPS全谱和(d) Ca、(e) F、(f) Mn的高分辨率谱; (g, h) CaF2:6%Mn2+纳米颗粒的TEM图

Figure 1. (a) The crystal structure of CaF2. (b) XRD patterns of CaF2:x%Mn2+ (x=0, 4, 5, 6, 7, 8) samples and the enlarged patterns in the region of 27.5°~30°. (c) Full XPS spectrum of CaF2:6%Mn2+ nanoparticles and high-resolution XPS spectrum of (d) Ca, (e) F and (f) Mn. (g, h) TEM images of CaF2:6%Mn2+ nanoparticles

图2. 室温下CaF2:x%Mn2+ (x=4, 5, 6, 7, 8)纳米颗粒的(a) PL光谱(λex=395 nm)和(b) PLE光谱(λem=525 nm). (a)中插图为Mn2+浓度与525 nm处发射峰归一化强度的关系图; (c) Mn2+离子的田边-菅野能级图(E为能级能量, B为拉卡参数, Dq为晶体场强度); (d)可见和(e)近红外检测器测得的CaF2:6%Mn2+纳米颗粒PL光谱. (d)中插图为5 K时, 该纳米颗粒的归一化PLE (λem=550 nm, λem=800 nm)和PL (λex=395 nm)光谱; (f) Mn2+-Mn2+二聚体发光机理图

Figure 2. (a) PL spectra (λex=395 nm) and (b) PLE spectra (λem=525 nm) of CaF2:x%Mn2+ (x=4, 5, 6, 7, 8) nanoparticles at room temperature. The inset in Figure 2(a) shows the relationship between Mn2+ concentration and emission peak normalized intensity at 525 nm. (c) Tanabe-Sugano energy level diagram of Mn2+ ion (E is the energy of the energy levels, B is the Racah parameter, and Dq is the crystal field strength). The PL spectra of CaF2:6%Mn2+ nanoparticles obtained (d) via the visible detector and (e) the near-infrared detector. Figure 2(d) inset shows the normalized PLE (λem=550 nm, λem=800 nm) and PL (λex=395 nm) spectra of the nanoparticles at 5 K. (f) Luminescence mechanism diagram of Mn2+-Mn2+ dimer

图3. CaF2:6%Mn2+纳米颗粒(a) Mn2+离子的PL光谱(λex=395 nm, 5~430 K)和(b) Mn2+-Mn2+二聚体PL光谱(λex=395 nm, 5~330 K); (c) Mn2+离子发光强度与温度的依赖性及相应测温模式下的Sr; (d) Mn2+-Mn2+二聚体发光强度的温度依赖性及相应的Sr; (e) Mn2+离子发射带质心与温度的关系及(f)对应的灵敏度

Figure 3. (a) PL spectra of Mn2+ ions (λex=395 nm, 5~430 K) and (b) Mn2+-Mn2+ dimers (λex=395 nm, 5~330 K) of CaF2:6%Mn2+ nanoparticles. (c) Dependence of luminescence intensity of Mn2+ ions on temperature and corresponding Sr. (d) Temperature dependence of the integrated emission intensity of Mn2+-Mn2+ dimers and Sr. (e) Centroid of the emission band of Mn2+ ions as a function of temperature and (f) corresponding sensitivities

图4. (a) CaF2:6%Mn2+纳米颗粒的二维PL等高线图(λex=395 nm, 5~305 K); (b) 5 K时的近红外PL光谱及其高斯拟合曲线; (c)获取Mn2+-Mn2+二聚体发射积分强度的方法示意图; (d)不同温度下, Mn2+离子与Mn2+-Mn2+二聚体的归一化发射强度直方图; (e) LIR(I550/I800)的温度依赖性及(f)对应的灵敏度; (g)在5~280 K之间经4次加热-冷却循环测量的LIR(I550/I800)值; (h) 280 K下测量30次PL光谱, LIR(I550/I800)值对应的波动情况及计算的δT值

Figure 4. (a) 2D PL contour map of CaF2:6%Mn2+ nanoparticles (λex=395 nm, 5~305 K). (b) Near-infrared PL spectrum at 5 K and its Gaussian fitting curve. (c) Diagram illustrating the methodology for determining the integrated emission intensity of Mn2+-Mn2+dimers. (d) Histograms of normalized emission intensity of Mn2+ ions and Mn2+-Mn2+ dimers at different temperatures. (e) Temperature-dependent LIR(I550/I800) values and (f) the corresponding sensitivities. (g) LIR(I550/I800) values measured by 4 heating-cooling cycles between 5~280 K. (h) The corresponding fluctuation of LIR(I550/I800) value obtained from PL spectra measured 30 times at 280 K and calculated δT value

图5. CaF2:6%Mn2+纳米颗粒的(a) Mn2+离子荧光衰减曲线(λex=395 nm, λem=550 nm, 5~430 K)和(d) Mn2+-Mn2+二聚体荧光衰减曲线(λex=395 nm, λem=800 nm, 5~330 K); (b) Mn2+离子荧光寿命和(e) Mn2+-Mn2+二聚体荧光寿命与温度的依赖性; (c) Mn2+离子荧光寿命和(f) Mn2+-Mn2+二聚体荧光寿命测温模式下, 不同温度下的Sa和Sr

Figure 5. (a) Mn2+ ion luminescent decay curves (λex=395 nm, λem=550 nm, 5~430 K) and (d) Mn2+-Mn2+ dimer luminescent decay curves (λex=395 nm, λem=800 nm, 5~330 K) of CaF2:6%Mn2+ nanoparticles; Temperature-dependent of (b) Mn2+ ion luminescent lifetime and (e) Mn2+-Mn2+ dimer luminescent lifetime; Sa and Sr for (c) Mn2+ ion luminescent lifetime and (f) Mn2+-Mn2+ dimer luminescent lifetime thermometry mode at various temperatures

图6. (a)基于CaF2:Mn2+的多功能测温方案以及(b)用于生物测温模型示意图

Figure 6. (a) A multifunctional temperature measurement scheme based on CaF2:Mn2+ nanoparticles and (b) schematic diagram for biological temperature sensing model

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Mn²⁺离子/二聚体差异化热响应的CaF₂纳米探针实现多模式光学测温

CaF₂ Nanoprobes with Mn²⁺ Ions/Dimers Exhibiting Differential Thermal Responses for Multimodal Optical Thermometry

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