Abstract
The feasibility of using laser-induced breakdown spectroscopy (LIBS) for the compositional analysis of ilmenite slag was explored. The slag was obtained from a pilot-scale ilmenite smelting furnace. The composition of major oxides TiO2, FeO, and MgO are determined by the calibrated LIBS method. LIBS measurements are done under normal atmosphere and temperature. A Q-switched Nd:YAG laser operating at 355 nm was used to create a plasma on an ilmenite slag sample. The characteristic lines based on the NIST database of Fe, Mg, and Ti can be identified on the normalized LIBS spectra for the slag samples. The spectral range chosen for the study is 370 to 390 nm. Calibration curves were plotted using the data collected from various industrial ilmenite samples of varying compositions of TiO2, FeO, and MgO. The univariate simple linear regression technique was used to do the analysis and the prediction accuracy was checked by the root mean square error (RMSE). To validate the application of LIBS, both qualitative and quantitative analysis is done and compared to the analytical ICP-OES results. The model predicts the magnesium content with the highest accuracy and gives good prediction for iron and titanium content. This study demonstrates the capability of using LIBS for the surface analysis of the ilmenite slag sample.
Highlights
Ilmenite smelting is a reduction process in which the FeO in ilmenite is reduced to Fe, giving a titanium-rich slag on top of pure pig iron [1]
The average plasma temperature lies between 13,000 and 16,000 K during the signal acquisition, for the samples considered for study (S1–S16), which is reasonable for a laser-induced breakdown spectroscopy (LIBS) plasma
The emission lines used for the calculation of electron density and local thermodynamic equilibrium (LTE) were Ti(I) 372.164 and Ti(II) 372.981 nm
Summary
Ilmenite smelting is a reduction process in which the FeO in ilmenite is reduced to Fe, giving a titanium-rich slag on top of pure pig iron [1]. Due to technical difficulties, this requirement is fulfilled by taking out a small amount of sample from the furnace and letting it cool, which is later sent to the laboratory, where suitable techniques (such as X-ray fluorescence) are used to analyze the slag for its composition. This consumes time, and during the test period the furnace consumes energy and feed material.
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