Effect of Melting Iron-Based Alloy Temperature on Carbon Content Observed in Laser-Induced Breakdown Spectroscopy

Our recent work has determined the carbon content in a melting ferroalloy by laser- induced breakdown spectroscopy (LIBS). The emission spectrum of carbon that we obtained in the laboratory is suitable for carbon content determination in a melting ferroalloy but we cannot get the expected results wh...

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Bibliographic Details
Published in:Plasma science & technology 2015-11, Vol.17 (11), p.933-937
Main Author: 林晓梅 常鹏辉 陈戈华 林京君 刘瑞祥 杨皓
Format: Article
Language:English
Subjects:
Carbon content
Error analysis
Errors
Ferroalloys
Laser induced breakdown
Melting
Spectroscopy
击穿
发射光谱
实验室条件
温度范围
激光诱导
熔融状态
碳含量
铁基合金
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Summary:Our recent work has determined the carbon content in a melting ferroalloy by laser- induced breakdown spectroscopy (LIBS). The emission spectrum of carbon that we obtained in the laboratory is suitable for carbon content determination in a melting ferroalloy but we cannot get the expected results when this method is applied in industrial conditions: there is always an unacceptable error of around 4% between the actual value and the measured value. By comparing the measurement condition in the industrial condition with that in the laboratory, the results show that the temperature of the molten ferroalloy samples to be measured is constant under laboratory conditions while it decreases gradually under industrial conditions. However, temperature has a considerable impact on the measurement of carbon content, and this is the reason why there is always an error between the actual value and the measured value. In this paper we compare the errors of carbon content determination at different temperatures to find the optimum reference temperature range which can fit the requirements better in industrial conditions and, hence, make the measurement more accurate. The results of the comparative analyses show that the measured value of the carbon content in molten state (1620 K) is consistent with the nominal value of the solid standard sample (error within 0.7%). In fact, it is the most accurate measurement in the solid state. Based on this, we can effectively improve the accuracy of measurements in laboratory and can provide a reference standard of temperature for the measurement in industrial conditions.
ISSN:1009-0630
DOI:10.1088/1009-0630/17/11/08