L. Kristjánsson ical interpretation appeared in several of his publica- tions, e.g., Einarsson (1957, 1962). Einarsson found that each series (zone) of lavas having "normal" or "reverse" polarity often consisted of tens of lava flows. He attempted to set up a scheme for the consecutive numbering of such polarity zones, especially in the strata emplaced during the cold climates of the last 3 m.y. Thus, zone N1 corresponded to the present mag- netic epoch, R1 contained lavas from the last reverse epoch, and so on. Each of these zones varied in thick- ness between locations, but N2 and R2 were of the order of 150 m and 300 m thick respectively, N3 was only some 50 m, and R3 was 500 m. Detailed work on worldwide volcanic sites dated by the potassium-argon (K-Ar) method in the 1960s, augmented by interpretation of magnetic anomaly lin- eations parallel to ocean ridges, revealed that on av- erage at least 3–4 reversals had occurred every mil- lion years in the Cenozoic era. Several versions of a "geomagnetic polarity time scale" for these reversals have been published, with each revision incorporat- ing additional reversal events named subchrons and cryptochrons (Ogg and Smith, 2004). It has been con- cluded from research on sedimentary and volcanic se- quences that at least ten such short events may have occurred in the current normal-polarity epoch (now known as the Brunhes chron) which began at 0.78 Ma, and the situation may be analogous for previous chrons. The secular variation has also been found to include many "excursions" of the VGP’s position to low latitudes. Due to this increasing complexity in our knowl- edge of the geomagnetic field behaviour, as well as to the scarcity of radiometric age determinations so far obtained from Icelandic lavas, any correspondence between Einarsson’s polarity zones and the geomag- netic polarity time scale is still uncertain. Einarsson (1962, p. 70) was also aware that one or more polarity zones might be missing in some of his profiles due to eruption rate variations, hiatuses or erosion. In some locations, the N2 might be tentatively identified with the Jaramillo normal-polarity subchron at 0.99–1.07 Ma, i.e., late in the Matuyama reverse magnetic chron which is supposed to span the interval 0.78–2.58 Ma ago (Ogg and Smith, 2004). However, in other places N2 could contain volcanics from an older long sub- chron in the Matuyama, namely the Olduvai at 1.78– 1.95 Ma. In southwest Iceland, this correlation finds some support in the K-Ar dating of a presumed N2 unit (Kristjánsson et al., 1980) which yielded an age of about 1.9 Ma (when recalculated with the decay constants used by Ogg and Smith). N3 may accord- ingly be the Reunion subchron which lasted between 2.13–2.15 Ma ago. In addition to collaborating with Einarsson on po- larity measurements in lava profiles, Sigurgeirsson (1957) designed a laboratory instrument for the ac- curate measurement of the primary remanence direc- tions in hand samples. Sigurgeirsson carried out a number of such determinations, mostly on lavas near the boundaries between polarity zones in Einarsson’s profiles in southwest Iceland. The best known of Sig- urgeirsson’s directional measurements are those at the R3-N3 boundary in various locations south of Hval- fjörður (H of Figure 1), resampled by Kristjánsson et al. (1980). Kristjánsson and Sigurgeirsson (1993), and others. This established that virtual poles formed an irregular path passing through low latitudes during the reversals, rather than the dipole simply decreasing to zero and then growing in the opposite sense while staying in near-axial orientation. It has also become clear from Icelandic data that the field intensity is re- duced during the reversal process, with the dipole field becoming weaker than non-dipole field components when the VGP latitude is less than 25◦ or so (Figure 9 of Kristjánsson, 2008). In 1964 a new stage began in paleomagnetic re- search on Icelandic lava sequences. That summer, a large collection of oriented drill cores was acquired by Doell (1972), mostly in Tjörnes (T of Figure 1) and the Snæfellsnes peninsula (S of Figure 1). An- other collection effort was carried out in 1964–1965 in southwest and east Iceland by a U.K. – Icelandic ex- pedition. In southwest Iceland the expedition sampled ten profiles of Pliocene and Pleistocene age, mapped by T. Einarsson around the Hvalfjörður fjord. The published account of this study (Wilson et al., 1972) was somewhat incomplete. Firstly, the altitudes of lava boundaries mapped by Einarsson were shown in diagrams, but very little information on the lithology 150 JÖKULL No. 60

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