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双光束热透镜光谱法测量热物理参数的准确性

Accuracy of Measurements of Thermophysical Parameters by Dual-Beam Thermal-Lens Spectrometry.

作者信息

Khabibullin Vladislav R, Franko Mladen, Proskurnin Mikhail A

机构信息

Analytical Chemistry Division, Chemistry Department, M.V. Lomonosov Moscow State University, d. 1, str. 3, Lenin Hills, GSP-1 V-234, Moscow 119991, Russia.

Laboratory for Environmental and Life Sciences, University of Nova Gorica, Vipavska 13, Rožna Dolina, 5000 Nova Gorica, Slovenia.

出版信息

Nanomaterials (Basel). 2023 Jan 20;13(3):430. doi: 10.3390/nano13030430.

DOI:10.3390/nano13030430
PMID:36770391
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9920435/
Abstract

Thermal-lens spectrometry is a sensitive technique for determination of physicochemical properties and thermophysical parameters of various materials including heterogeneous systems and nanoparticles. In this paper, we consider the issues of the correctness (trueness) of measurements of the characteristic time of the thermal-lens effect and, thus, of the thermal diffusivity determined by dual-beam mode-mismatching thermal lensing. As sources of systematic errors, major factors-radiation sources, sample-cell and detector parameters, and general measurement parameters-are considered using several configurations of the thermal-lens setups, and their contributions are quantified or estimated. Furthermore, with aqueous ferroin and Sudan I in ethanol as inert colorants, the effects of the intermolecular distance of the absorbing substance on the correctness of finding the thermophysical parameters are considered. The recommendations for checking the operation of the thermal-lens setup to ensure the maximum accuracy are given. The results obtained help reducing the impact of each investigated factor on the value of systematic error and correctly measure the thermophysical parameters using thermal-lens spectrometry.

摘要

热透镜光谱法是一种用于测定包括非均相体系和纳米颗粒在内的各种材料的物理化学性质和热物理参数的灵敏技术。在本文中,我们考虑了热透镜效应特征时间测量的正确性(准确性)问题,进而考虑了由双光束模式失配热透镜法测定的热扩散率的正确性问题。作为系统误差源,我们使用热透镜装置的几种配置,考虑了主要因素——辐射源、样品池和探测器参数以及一般测量参数,并对它们的贡献进行了量化或估计。此外,以亚铁菲绕啉水溶液和乙醇中的苏丹I作为惰性着色剂,考虑了吸收物质分子间距离对热物理参数测定正确性的影响。给出了检查热透镜装置运行以确保最大精度的建议。所获得的结果有助于减少每个研究因素对系统误差值的影响,并使用热透镜光谱法正确测量热物理参数。

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