Using equilibrium thermodynamics to study thermochemical processes in arc discharges used in atomic emission spectral analysis (review)

Q4 Chemistry
A. Pupyshev
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引用次数: 1

Abstract

Until the beginning of the 21st century, the arc discharge was the main source of excitation of the atomic spectra of elements during routine atomic emission spectral analysis. The wide application of this spectral source at the same time aroused great interest of analysts in the study of complex thermochemical processes occurring at its electrodes and in the discharge plasma. This was due to the need to improve the metrological and informational characteristics of the analysis. Equilibrium thermodynamics has often been used to carry out such studies. It is shown that three levels of the thermodynamic approach can be distinguished here, differing in the complexity of the applied apparatus of thermodynamics and the information content of the results obtained. Numerous examples of the application of these levels of approach to the study of thermochemical processes occurring in the electrode or in the discharge plasma are given. The main advantages and disadvantages of the approaches used, which provide only qualitative information about the ongoing processes, are noted. The main disadvantage is the impossibility of predicting the composition of the arc plasma from the initial composition of the condensed sample. The most informative is the generalized thermodynamic model of thermochemical processes in a DC arc discharge from the sample surface and from the electrode crater. The model is based on the division of a non-stationary non-equilibrium system of an arc discharge into successive quasi-stationary subsystems. They correspond to the stage of sample evaporation and thermochemical transformation of its components in the discharge plasma. According to the model, the total equilibrium composition of the evaporated sample is initially calculated. This determines the initial composition of the arc plasma. Then, the total equilibrium composition of the arc plasma is calculated and the transition to the intensities of the spectral lines of the analytes is performed. The correctness of the generalized model, which gives semi-quantitative results, is confirmed by comparison with experimental data.
利用平衡热力学研究原子发射光谱分析中电弧放电的热化学过程(综述)
直到21世纪初,在常规原子发射光谱分析中,电弧放电一直是元素原子光谱的主要激发源。该光谱源的广泛应用同时引起了分析人员对其电极和放电等离子体中发生的复杂热化学过程的极大兴趣。这是由于需要提高分析的计量和信息特性。平衡热力学经常被用来进行这类研究。结果表明,热力学方法可分为三个层次,不同的是热力学应用设备的复杂程度和所得结果的信息量。这些水平的方法应用于研究发生在电极或放电等离子体中的热化学过程的许多例子给出。注意到所使用的方法的主要优点和缺点,这些方法只提供有关正在进行的过程的定性信息。这种方法的主要缺点是不可能根据冷凝样品的初始成分来预测电弧等离子体的组成。最具信息量的是样品表面和电极凹坑直流电弧放电热化学过程的广义热力学模型。该模型基于将非平稳非平衡电弧放电系统划分为连续的准平稳子系统。它们对应于放电等离子体中样品蒸发及其组分热化学转化的阶段。根据该模型,初步计算了蒸发样品的总平衡组成。这决定了电弧等离子体的初始成分。然后,计算电弧等离子体的总平衡组成,并进行分析物谱线强度的转换。通过与实验数据的比较,证实了广义模型的正确性,并给出了半定量结果。
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来源期刊
Analitika i Kontrol
Analitika i Kontrol Chemistry-Analytical Chemistry
CiteScore
0.90
自引率
0.00%
发文量
15
期刊介绍: Analitika i Kontrol is a scientific journal covering theoretical and applied aspects of analytical chemistry and analytical control, published since autumn 1997. Founder and publisher of the journal is the Ural Federal University named after the first President of Russia Boris Yeltsin (UrFU, Ekaterinburg).
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