Leó Kristjánsson would have an inclination at +77.2◦ in the present area. The average of virtual poles from all the lavas is at 88.3◦N, 130◦E, with a vector sum of R = 308.5, and a 95% confidence angle of 3.1◦. It should be noted that the occurrence of groups of low-latitude virtual poles may cause some bias in these averages, for in- stance the ten flows VR 9–10, VS 3–8, 29–30 with similar poles near the Equator. Low-field thermomagnetic curves were obtained in air from five samples, using a Bartington MS2W furnace and susceptibility meter. These curves have quite variable shapes, as noted also by Kristjánsson et al. (2003). Their final Curie points are in the range 500–600◦C but there is always evidence of some al- teration and irreversibility on heating, cf. also the next paragraph. It may therefore be difficult to find lava samples in Northwest Iceland suitable for paleointen- sity studies by conventional methods. Kristjánsson (1967) contemplated the possible use of magnetic properties as a geothermometer, i.e. an indicator of maximum temperatures experienced by lava flows on burial within the pile. If a significant permanent change occurs in for instance the rema- nence intensity, coercive force, or susceptibility of a stably magnetized sample upon heating in the labora- tory to a temperature T and cooling to room tempera- ture, a simple interpretation would indicate that previ- ous secondary heating of the sample while still in situ, did not reach T. This simple model was tested by heat- ing eight very stable lava specimens of both polarities from near sea level in Arnarfjörður and Tálknafjörður to 100◦C and 160◦C in field-free space. The room- temperature susceptibilities increased in all cases, by an average of 2.5% and 6% respectively, and inten- sities had decreased altogether by an average of 1.5% after the 160◦C heating. Similar results were obtained by Kristjánsson (1967) on samples collected near Ísa- fjarðardjúp and heated in air. As a precaution against oxidation of the magnetic minerals, the heating to 160◦C was in the present case carried out in oil. It may be tentatively con- cluded that the exposed lava pile in these two parts of the Northwest peninsula has not experienced heat- ing above 100◦C. Reasonable estimates of geothermal gradients, as well as the observed near-absence of ze- olite infillings in most of the present profiles, also make it unlikely that temperatures at the present sea level ever reached 100◦C (cf. Kristjánsson and Jóns- son, 2007, p. 33). CONCLUSIONS This study is a first attempt to i) use variations in the geomagnetic field, along with other infor- mation, to strengthen correlations between strata on the three southwesterly promontories of the North- west peninsula of Iceland, between Arnarfjörður and Breiðafjörður ii) set up a common scheme of polar- ity zones for the area. The lava pile in the area has suffered little alteration, compared to other areas of similar or even younger age in Iceland. These lavas may therefore present good opportunities for radio- metric dating of polarity-zone boundaries and geo- logical events, as well as for geochemical investiga- tions. Measurements of magnetic remanence direc- tions yielded very stable and consistent results, and the possibility of using these and other magnetic prop- erties as a qualitative geothermometer in the basalt lava pile is suggested. Like other Icelandic basalts however, the lavas in this area do not seem to be ideal material for paleointensity studies using conventional whole-rock methods. Polarity zones in the Arnarfjörður-Breiðafjörður area appear to be relatively thick (for instance over 40 lavas in profiles TE and AB), and there are other in- dications that the lava production has sometimes been proceeding quite rapidly. Thus, Table 2 includes some 50 cases of two or more successive lavas having rema- nence directions that are similar within 10◦ of arc or less. This may be compared to current secular varia- tion rates of the order of 5◦ per century, and the num- ber of such groups is well in excess of what may be attributed to chance. In addition to flows VS 3–8 and AC 1–6 mentioned above, three or more similar suc- cessive directions occur for instance in TE 7–13, AJ 7–10, RS 8–11 and TW 6–9. It appears that by the use of reversals and large ap- parent geomagnetic excursions (Figure 4a,b) recorded in the lava pile, correlation has been established be- tween all the profiles FD and TR/TS on the south side of Tálknafjörður, VR on the north coast of Pat- 48 JÖKULL No. 59

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