Determination of S, Ni, Cu in copper-nickel sulfide ores by total reflection X-ray fluorescence analysis: experience of participation in the interlaboratory comparisons

The quality of the determination of S, Ni, Cu in copper-nickel sulfide ores was assessed in the framework of the program for interlaboratory comparative tests (ICT) using total reflection X-ray fluorescence analysis (TXRF) taking into account the criteria for methods for determining the chemical composition of mineral raw materials. Certified TXRF techniques for the analysis of mineral materials are absent, so the interlaboratory comparison test was used to control and improve the accuracy of measurements by TXRF. Powdered ore samples were prepared as suspensions by wet grinding: 100 mg of the powder, 4 ml of ultra-pure water and 250 μl of the Ga standard solution were milled using 20 g of ZrO₂ balls 1 mm in diameter in the mixing mill for 10 minutes at a frequency of 20 Hz. The ratio of the intensities of the characteristic lines of the analyzed elements and the Ga internal standard was chosen as an analytical signal. To plot calibration curves, a set of ore reference samples was analyzed using certified procedures (atomic absorption spectrometry for Cu, Ni, gravimetry for S). The quality of the TXRF analysis was assessed by the value of Z-criterion. The measurement error did not exceed 5 rel. %. The relative percentage differences between the TXRF results and the results obtained in the interlaboratory study was less than 10%. The described method can be used for rapid analysis of copper-nickel sulfide ores.

1. N. M. Fedorovsky All-Russian Research Institute of Mineral Raw Materials. https://vims-geo.ru/ru/activity/mimo/msi [in Russian] (accessed 12.03.2024).

2. Chepkova I. F., Kreynin S. V., Ponomareva O. I. Interlaboratory comparisons as evidence base for the competence of laboratories / Industr. Lab. Mater. Diagn. 2018. Vol. 84. N 2. P. 70 – 72 [in Russian]. DOI: 10.26896/1028-6861-2018-84-2-70-72

3. Ivanov A. V., Demonterova E. I., Revenko A. G., et al. History and current state of analytical research at the Institute of the Earth’s Crust SB RAS: Centre for geodynamics and geochronology / Geodin. Tektonofiz. 2022. Vol. 13. N 2 [in Russian]. DOI: 10.5800/GT-2022-13-2-0582

4. Maltsev A. S., Pashkova G. V. Application of total-reflection X-ray fluorescence spectrometry (TXRF) to geological objects: experience of the TXRF laboratory, center for geodynamics and geochronology / Geodin. Tektonofiz. 2022 [in Russian]. DOI: 10.5800/GT-2022-13-2s-0601

5. Pashkova G. V., Chubarov V. M., Akhmetzhanov T. F., et al. Total-reflection X-ray fluorescence spectrometry as a tool for the direct elemental analysis of ores: Application to iron, manganese, ferromanganese, nickel-copper sulfide ores and ferromanganese nodules / Spectrochim. Acta, Part B. 2020. Vol. 168. 105856. DOI: 10.1016/j.sab.2020.105856

6. Alov N., Sharanov P. Elemental Analysis of Copper-Zinc Ores by Total Reflection X-Ray Fluorescence using Nonaqueous Suspensions / Anal. Lett. 2018. Vol. 51. N 11. P. 1789 – 1795. DOI: 10.1080/00032719.2017.1390758

7. Fernández-Ruiz R., Friedrich K. E. J., Redrejo M. J. Effect of modulation of the particle size distributions in the direct solid analysis by total-reflection X-ray fluorescence / Spectrochim. Acta. Part B. 2018. Vol. 140. P. 76 – 83. DOI: 10.1016/j.sab.2017.12.007

8. Sharanov P. Y., Volkov D. S., Alov N. V. Quantification of elements in copper-zinc ores at micro- and macro-levels by total reflection X-ray fluorescence and inductively coupled plasma atomic emission spectrometry / Anal. Methods. 2019. Vol. 11. P. 3750 – 3756. DOI: 10.1039/C9AY01055F

9. Sharanov P. Yu., Alov N. V. Total reflection X-ray fluorescence analysis of solid metallurgical samples / J. Anal. Chem. 2018. Vol. 73. N 11. P. 1085 – 1092. DOI: 10.1134/S1061934818110126

10. Pashkova G. V., Zhilicheva A. N., Chubarov V. M., et al. Improvement of suspension-assisted total reflection X-ray fluorescence analysis of ores using wet grinding and empirical calibrations / Spectrochim. Acta. Part B. 2022. Vol. 198. 106549. DOI: 10.1016/j.sab.2022.106549

11. Hubbard C. R., Snyder R. L. RIR — Measurement and Use in Quantitative XRD / Powder Diffr. 1988. Vol. 3. N 2. P. 74 – 77. DOI: 10.1017/S0885715600013257

12. Diuzhikov O. A., Distler V. V., Strunin B. M., et al. Geology and ore content of the Norilsk region. 1988. — 279 p. [in Russian].

13. Smagunova A. N., Karpukova O. M. Methods of mathematical statistics in analytical chemistry. — Irkutsk, 2008. — 339 p. [in Russian].

14. Unterumsberger R., Beckhoff B., Gross A., et al. A round robin test for total reflection X-ray fluorescence analysis using preselected and well characterized samples / J. Anal. At. Spectrom. 2021. Vol. 36. N 9. P. 1933 – 1945. DOI: 10.1039/D1JA00103E