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XRF Analysis of Vegetation Samples and its Application to Mineral Exploration

Published online by Cambridge University Press:  06 March 2019

T. K. Smith
Affiliation:
Institute of Geological Sciences, London and Keyworth, United Kingdom
T. K. Ball
Affiliation:
Institute of Geological Sciences, London and Keyworth, United Kingdom
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Extract

Many analysts use a wet or dry oxidation treatment prior to determination of minor and trace elements in non-fossilised vegetation. This stage is often unnecessary for XRFS since the technique is sufficiently sensitive for many purposes to permit the analysis of unashed material. Indeed, inaccurate results may be obtained if volati1es are lost, if no correction is made for loss on ignition, or if such correction is of large magnitude.

Type
VIII. XRF General Applications
Copyright
Copyright © International Centre for Diffraction Data 1982

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References

1. Bowen, J. M., Use of sodium and potassium nitrates for decomposing organic samples for elementary analysis. Anal. Chem. 40:969 (1968).Google Scholar
2. Strohal, P., Lucic, S. and Jelisavcic, O., The loss of cerium, cobalt, manganese, protactinium, ruthenium and zinc during dry ashing of biological material. Analyst 94:678 (1969).Google Scholar
3. Gleit, C. E. and Holland, W. D., Use of electrically excited oxygen for the low temperature decomposition of organic substances. Anal. Chem. 34:144 (1962).Google Scholar
4. Jenkins, R., Hurley, P. W. and Shorrocks, V. M., Plant mineral analysis by X-ray fluorescence spectrometry. Analyst 91:935 (1966).Google Scholar
5. Norrish, K. and Hutton, J. T., Plant analyses by X-ray spectrometry. X-Ray Spectrometry 6:6 (1977).Google Scholar
6. de Jongh, W.K., X-ray fluorescence analysis applying theoretical matrix corrections. Stainless steel. X-Ray Spectrometry 2:151 (1973).Google Scholar
7. Rice, R. and Sharpe, G. J., Copper mineralisation in the forest of Coed-y-Brenin, North Wales, Trans. Instn. Min. Metal 1. 85:B1 (1976).Google Scholar
8. Dunn, C. E., The biogeochemical expression of deeply burled uranium mineralisation in Saskatchewan, Canada. 1-G eochem. Explor. 15:437 (1931).Google Scholar
9. Rose, A. W., Hawkes, H. E. and Webb, J. S., “Geochemistry in Mineral Exploration,” Academic Press, London (1979).Google Scholar