lamellae of pure ilmenite appear at this stage restricted to directions parallel to octahedral planes in the titanomagnetite host. Hydrothermal alteration is defined by granu- lation and titanohematite flecking but may now also include alteration of ilmenite lamel- lae to blue-black iron-bearing sphene replacements at temperatures higher than 250°C. Class 3: This only differs from class 2 in the extent of the ilmenite lamellae which now cover half or more of the grain so that the residual magnetite approaches Fe304 in com- position. Hydrothermal alteration is similar to class 2 although grains are less susceptible to granulation. Class 4: With further oxidation the ilmenite lamellae break down into fine titanohematite and ferrirutile aggregates causing a whitening of the lamellae and volume increase. Hydrothermal alteration may be evidenced by pod-like titanohematite and ferrirutile lamellae. Class 5: In this class islands of magnetite contain black spinel rods and are separated by broad oxidised ilmenite lamellae. Class 6: The original titanomagnetite grain is now entirely pseudomorphed by tit- anohematite, ferri-rutile and pseudobrookite. Like titanomagnetite, ilmenite also responds to hydrothermal alteration with formation of a dark blue-black iron-bearing sphene at temperatures of about 250° and goes to form a clothwork texture of two phases at temper- atures in excess of 300°C. Maghemitisation of titanomagnetite grains is quite extensively observed in this collection (Table 1). It is identified here exclusively in grains which have undergone conchoidal fracture due to possible lattice compression, and have taken on a pale blue-grey colouration (often milky or cloudy in texture). These grains have developed in them a lattice-like network of alteration which nor- mally starts from the grain edges and proceeds inwards. All of these characteristics are dis- tinct frorn the effects of deuteric oxidation or granulation. METHOD Polished sections were analysed with a Zeto-pan Pol microscope at x 1200 magnifi- cation by making continuous traverses across- the sample, and classifying the deuteric oxidation state of each magnetite and ilmenite grain with more than 50% of its area falling within the field of view; any doubt concerning the correct class of a grain was resolved by placing it in the lower class. Since there are often considerable and rapid spatial vari- ations within a rock unit with individual grains only a few microns apart differing in their oxidation state, it is essential to adopt a statistical approach, and in this study a minimum of 50—60 grains were examined in each section to establish an arithmetic mean oxidation state. Grain dimensions were also measured and a granulation (G) and magh- emitisation (Mh) index running from 0 to 3 assigned to the titanomagnetite grains according to the area of grain (0%,< 33%, 33—66% and 66%) affected. Maghemite is '1 Fe203, a low temperature oxidised version of magnetite with an inverse spinel structure in- cluding a few missing iron atoms; its extent proved to be a difficult parameter to quantify and it was subjectively considered that a 0—3 subdivision by area was the most realistic assessment. RESULTS Seventy-eight dykes showing no visible weathering in hand specimen were selected for study and salient results are listed in Table 1 (copy of full results obtainable from authors). Thirty-four dykes exhibit no deuteric oxidation and the remainder show oxidation classes up to but not exceeding 3; only in one site (64) is deuterically-oxidised ilmenite ob- served. In a less rigorous survey by Fowler (1975) of 40 Reydarfjördur lavas, the majority of which were massive tholeiities (sampling localities given by Piper et al. 1977, Fig. 4), no significant difference in average oxidation state was found between normal and reversed 36 JÖKULL 30. ÁR

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