could not account for such grouping of polarities by self-reversal, local field anomalies, tectonics, or temporary phenomena. Tests of stability, within- sample consistency, and magnetic behaviour on heating, produced positive results. Alongwith bak- ed-contact studies which began elsewhere in the early to middle fifties, Hospers’ work provided some of the strongest evidence to convince earth scientists of the reality of global geomagnetic reversals (see e.g. conference report in Nature, 17 Nov 1956). Hospers estimated the length of time covered by each polarity group to be 0. 25-0. 5 M. y., and he demonstrated their possible use in stratigraphic correlation (Hospers 1954c). However, it must be remembered that Hospers generally measured only one sample per lava flow in the laboratory, without any demagnetization treatment. Someofhis results from Snaefellsnes were later revised by Doell (see below). R. A. Fisher (1953) had developed normal statis- tics on a spherical surface, to use in analysis of directional measurements. The first application of these was to Hospers’ Icelandic data. To quote Sir Ronald himself (in a letter to T. Einarsson, dated 21 May 1955), they provided a “tolerably expeditious method by which the observations can be combined and summarized”, and they have in fact been used for all within-unit calculations of directional dis- persions to the present day. Fisher’s statistics have also been widely used for between-unit paleo- magnetic dispersion (i.e. secular variation) esti- mates, although there is some doubt as to their applicability in that case. For historical back- ground, see J. Hospers’ book review in Tecton- ophysics vol. 5, p. 345-352, 1968. T. EINARSSON, T. SIGURGEIRSSON, A. BRYNJOLFSSON Hospers’ work was soon to be continued by Ice- landic scientists who realized its potential as a geo- logical mapping aid in the volcanic pile. Their studies began in 1953. Einarsson and Sigurgeirsson 11955) and Einarsson (1957a, b) pioneered the measurement of magnetic polarity in rocks by means of a compass in the field, and measured thousands of lava flows across Iceland using this method. It was soon found in this way that the intensity of primary remanence decreased with increasing age and alteration, so that measure- ment could be difficult, or this primary remanence might be masked by secondary or induced magnet- ization. These problems could, however, be mini- mized by sampling from the bottom contact zone of flows. The polarity measurements were important in Einarsson's stratigraphic mapping of long sections through the volcanic pileofSW-Iceland andcentral W-Iceland, and E-Iceland where about 30 polarity zones were mapped (Einarsson 1957a). There were also more detailed regional studies, e.g. in Snaefells- nes, central N-Iceland, and Tjörnes (Einarsson 1958a, b, 1959,1962,1963). Einarsson found that the average thickness of magnetic polarity zones was 200-350 m, and he initiated a numbering system for these (Nl, Rl, N2,...). The conclusion of Einarsson and Sigurgeirsson (1955) that normal and reverse polarity zones have approximately equal mean thicknesses, has been confirmed by subsequ- ent work. Einarsson’s polarity results from lavas have also been found to be very reliable, but he has expressed reservations about the value of such mea- surements on clastics and sediments (Einarsson and Sigurgeirsson 1953, Einarsson 1957c). Due to dating difficulties, Einarsson’s polarity zones have only to a limited extent been correlated with other geomagnetic polarity timescales. There are also ambiguities in long-distance correlations of these zones within Iceland because of the very diff- erent rates of buildup of the lava pile in different parts of the country. Sigurgeirsson (1957) and Brynjolfsson (1956, 1957) de- signed a sensitive shielded 5-Hz rotation magneto- meter (Fig.3) for the measurement of remanence in hand samples of rock, and one-axis a-c demagne- tization apparatus that reached 140 Oe peak field. This equipment was used for accurate direction determination in several hundred lava samples. Those measurements that were published in detail included a study of a lava section through a gradual geomagnetic polarity transition in the mountains of the Hvalfjörður area. It was suggested by their results that a polarity zone corresponded to 0. 1-1 M. y. [Einarsson 1958a), that the reversal process took of the order of 1000 years, and that the geö- magnetic field was likely to have weakened con- siderably during these transitions. The Hvalfjördur location was one of the very few known sites in the world for a decade or more to yield details on geo- magnetic transitions, but their existence was very important evidence on the nature and long-term behaviour of the geomagnetic field. Various theoretical and experimental work on the magnetization and demagnetization processes 94 JÖKULL 32. ÁR

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