On the neutron absorption properties of basic and ultrabasic rocks: the significance of minor and trace elements

doi:10.1144/GSL.SP.2005.240.01.16

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Geological Society, London, Special Publications; 2005; v. 240; p. 207-217;
DOI: 10.1144/GSL.SP.2005.240.01.16
© 2005 Geological Society of London

On the neutron absorption properties of basic and ultrabasic rocks: the significance of minor and trace elements

P. K. Harvey & T. S. Brewer

Department of Geology, University of Leicester, Leicester, LE1 7RH, UKpkh{at}leicester.ac.uk

The neutron absorption macroscopic cross-section, ${Sigma}$ , is measuredroutinely by neutron porosity tools and, although rarely presentedas a logging curve in its own right, is used indirectly forthe estimation of (neutron) porosity. One of the reasons thatthis primary measurement is not often employed directly in petrophysicalanalysis is the difficulty of interpretation. In particular,little is known about the range of ${Sigma}$ values for common lithologies,or exactly what information the measurement is providing.

In this contribution we demonstrate that excellent estimatesof ${Sigma}$ can be calculated, provided that the chemistry of a sampleis known in sufficient detail. When applied to a range of geochemicalreference materials, it becomes apparent that the minor andtrace elements present may have a profound effect on the ${Sigma}$ valueof a sample, and, in turn, on the interpretation of neutronporosity measurements. Using this approach we present ${Sigma}$ datafor basaltic and ultrabasic rocks, and model the change in ${Sigma}$ with alteration.

Alteration is considered in these models as an increase in alterationminerals (which are mainly clays, but also carbonates and zeolitesin basic rock alteration) and changes in the trace-element chemistryof the rocks. Of the trace elements, boron and some of the rare-earthelements are of particular importance. Modelling the variationin ${Sigma}$ with these mineralogical and compositional changes indicatesthat increases in boron are the most important of these factorsin increasing ${Sigma}$ ; this is enhanced by the alteration, particularlyto clay phases, which generally accompanies an increase in boron.

These models suggest that a ${Sigma}$ log should be able to act as aproxy for alteration trends in basic and ultrabasic crystallinerocks, and a quantitative model for such alteration is described.

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