Stratigraphy and paleomagnetism of a 2.9-km composite lava section in Eyjafj�rdur, Northern Iceland: a reconnaissance study

Kristjánsson, Leó; Guðmundsson, Ágúst; Harðarson, Björn S.

doi:10.1007/s00531-004-0409-4

Cited by 11 publications

(25 citation statements)

References 23 publications

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“…However, later research has indicated that the volcanic productivity is quite episodic, and dating of a thick normal-polarity zone in Northwestern Iceland (McDougall et al, 1984) did not yield the expected agreement with the two thick zones dated previously. In some cases the paleomagnetic directions in successive lavas are serially correlated, indicating that the time interval between these lavas is less than 1 kyear (Kristjansson et al, , 2004. In other cases there may be hiatuses of 100 kyear and more between lava flows, not detectable from geologic observations or from radiometric dating at the present level of resolution.…”

Section: Some Further Resultsmentioning

confidence: 84%

“…Other examples are found in papers by Sigurgeirsson (1957), Kristjansson (1995) and Kristjansson et al (2004). Field mapping of remanence directions in late-glacial lavas of the Reykjanes peninsula, initiated by A. Gudmundsson in the mid-1970s, revealed that in several hills all exposed lava flows were erupted during a geomagnetic transition or major excursion of the field (Levi et al, 1990).…”

Section: Some Further Resultsmentioning

confidence: 95%

“…Hence, there is no worthwhile gain in quality by applying further demagnetization (see e.g. Watkins and Walker, 1977;Kristjansson et al, 2003Kristjansson et al, , 2004 or sophisticated methods of statistical processing. As an example of the excellent reproducibility of directional results, it may be mentioned that a series of 22 basalt lavas in Southern Iceland was sampled and measured both by Kristjansson et al (1988) and Tanaka et al (1995).…”

Section: On the Significance Of Directional Results From Any Single Smentioning

confidence: 99%

“…However, variations by up to 10 • in mean pole positions between parts of the large 1964-65 Eastern Iceland paleomagnetic survey were noted by Wilson and McElhinny (1974); these were unlikely to be due to chance in a collection of independent data. Differences of this size have also been noted subsequently, even between collections of up to 300 lava flows spanning several reversals (see Kristjansson et al, 2003Kristjansson et al, , 2004 but the reasons for these variations remain obscure. It is possible that they are partly caused by regional magnetic anomalies of crustal origin, presence of clustered atypical directions due to episodicity of the volcanism, inaccurate tectonic corrections, or some small directional bias in the orientation of samples during collection and measurement.…”

Section: Mean Fields Mean Poles and Normal-reverse Asymmetriesmentioning

confidence: 90%

“…However, no In the stippled area, basement rocks are less than 0.8 Ma old, and we also indicate the position of the 10 Ma isochron (Saemundsson, 1986). The numbers refer to publications where the composite surveys are reported, as follows: (1) Watkins and Walker (1977); (2) Helgason (1982), Bleil et al (1982); (3) Kristjansson et al (1995); (4) McDougall et al (1976b) and Kristjansson and Gudmundsson (2005); (5) Helgason and Duncan (2001); (6) Saemundsson et al (1980); (7) Kristjansson et al (1992); (8) Kristjansson et al (2004); (9) Doell (1972), Kristjansson et al (1988), Eiriksson et al (1990); (10) McDougall et al (1984); (11) Kristjansson and Johannesson (1996); (12) Kristjansson et al (2003); (13) ; (14) Kristjansson and Johannesson (1999); (15) Kristjansson et al (1980); (16) Kristjansson et al (1991); (17) Kristjansson and Gudmundsson (2001). certain correlations between distant parts of the country, using e.g. particular geomagnetic epochs or extensive clastic horizons, have been found so far.…”

Section: Stratigraphy: Work Since 1972mentioning

confidence: 97%

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Paleomagnetism and magnetic anomalies in Iceland

Kristjánsson

Jónsson

2007

Journal of Geodynamics

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Section: Some Further Resultsmentioning

confidence: 84%

Section: Some Further Resultsmentioning

confidence: 95%

Section: On the Significance Of Directional Results From Any Single Smentioning

confidence: 99%

Section: Mean Fields Mean Poles and Normal-reverse Asymmetriesmentioning

confidence: 90%

Section: Stratigraphy: Work Since 1972mentioning

confidence: 97%

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Paleomagnetism and magnetic anomalies in Iceland

Kristjánsson

Jónsson

2007

Journal of Geodynamics

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U–Pb zircon age and chronology of the Torfufell central volcano: implications for timing of rift relocation in North Iceland

Árnadóttir,

Thordarson,

Hjartarson

et al. 2023

Bull Volcanol

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The Late-Miocene Torfufell central volcano (ToCV), situated between the now extinct Snæfellsnes-Húnaflói rift zone and the presently active rift in North Iceland, provides an excellent opportunity to recreate the construction history of a volcanic edifice. We present new U–Pb zircon ages from six silicic units of the ToCV. The results range from 7.15 ± 0.12 to 6.76 ± 0.02 Ma, taken here to represent a ~ 400 kyr time-span for silicic activity at the volcano. Before that, the central volcano had produced basaltic lavas for 600–800 kyr, implying that it was active for ~ 1–1.2 Myr. A stratigraphically documented ~ 1 Myr hiatus above the volcano is contemporaneous with, but shorter than, a major unconformity in the Flateyjarskagi peninsula, considered to result from a major rift relocation in North Iceland. The new U–Pb ages show that silicic volcanism at the ToCV took place 1–2 Myr earlier than assumed previously and nearly synchronously with the rift relocation. As the age progression of the ToCV and the neighboring 5–6 Ma Tinná central volcano conflicts with the generally established geotectonic framework of central N-Iceland, we propose that these two volcanoes were formed at a leaky transform zone that developed to accommodate the rift relocation, with the ToCV formed at its junction with the embryonic rift zone, thus marking the initiation of the presently active rift in North Iceland. Since then, the two volcanoes have drifted away from the rift system due to plate spreading and migration of the plate boundary relative to the Iceland mantle plume.

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Heterogeneous nickel isotope compositions of the terrestrial mantle – Part 2: Mafic lithologies

Saunders

Barling

Harvey

et al. 2022

Geochimica et Cosmochimica Acta

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We report stable Ni isotope compositions (δ 60/58 Ni, relative to SRM986) for mafic lavas with a range of -0.16 ‰ to +0.20 ‰ (n=44), similar to that of peridotite samples. Ocean island basalts (OIB) have been analysed from Iceland (n=6), the Azores (n=3), the Galápagos Islands (n=2), and Lōʻihi, Hawaii (n=1). Samples from Iceland (average δ 60/58 Ni = +0.13±0.16‰, 2s, n=7) display the greatest range in Ni isotope compositions from a single OIB location in this work, of +0.01 ‰ to +0.23 ‰. Samples from the Azores (average δ 60/58 Ni = -0.10±0.10 ‰, 2s) and Galápagos (average δ 60/58 Ni = -0.01±0.04 ‰, 2s) are generally isotopically lighter. The single Lōʻihi sample has a δ 60/58 Ni of +0.17 ‰. The lightest analysed bulk rock δ 60/58 Ni in this work, -0.16 ‰, is from the Azores island, Pico. Enriched mid ocean ridge basalts (E-MORB), which have (La/Sm)N>1, are isotopically lighter than normal type MORB (N-MORB), as shown by data from the Mid Atlantic Ridge (n=9) and East Pacific Rise (n=3). All E-MORB average δ 60/58 Ni = Heterogeneous Ni isotope compositions of the terrestrial mantle: Part 2 2 +0.00±0.06 ‰ (2s, n=7), whereas N-MORB average δ 60/58 Ni = +0.14±0.10 ‰ (2s, n=5).A suite of 15 mafic samples from the Cameroon Line, comprising lithologies ranging from nephelinites to hypersthene-normative basalts, have Ni isotope compositions that are identical within analytical uncertainty (average δ 60/58 Ni = +0.08±0.06 ‰, 2s). Similarly, MORB samples display no relationship between δ 60/58 Ni and geochemical indicators of degree of partial melting or fractional crystallisation. Host lavas for two previously analysed ultramafic xenolith suites have δ 60/58 Ni identical to the average δ 60/58 Ni of their respective xenolith suites. This is consistent with previously published evidence from peridotites and komatiites that Ni isotopes are not greatly fractionated by melting. Therefore, mafic rocks may preserve the δ 60/58 Ni of their mantle source. Sampling a greater volume of mantle, their average Ni isotope composition +0.07±0.17 ‰ (2s, n=44) may also be a better representation of the Bulk Silicate Earth (BSE), than estimates based purely on peridotites.The δ 60/58 Ni of MORB co-varies with La/Sm, Rb/Sr, europium anomaly (Eu/Eu*), and K2O/(K2O+Na2O).The relationships between these parameters and δ 60/58 Ni are consistent with mixing between two model endmembers. One could be depleted MORB or depleted MORB mantle (DMM) with a relatively heavy Ni isotope composition; the other a more enriched endmember that has isotopically lighter δ 60/58 Ni. The link between lighter δ 60/58 Ni and enriched lithologies in the mantle is further supported by published evidence of light Ni isotope compositions associated with some pyroxenite xenoliths. However, the curvature of the apparent mixing arrays defined by basalts is hard to reconcile with admixing of geochemically enriched but isotopically fractionated oceanic crustal lithologies. High [Ni] enriched magmas such as kimberlites may be a closer match to the enriched endmember. Ho...

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Stratigraphy and paleomagnetism of a 2.9-km composite lava section in Eyjafj�rdur, Northern Iceland: a reconnaissance study

Cited by 11 publications

References 23 publications

Paleomagnetism and magnetic anomalies in Iceland

Paleomagnetism and magnetic anomalies in Iceland

U–Pb zircon age and chronology of the Torfufell central volcano: implications for timing of rift relocation in North Iceland

Heterogeneous nickel isotope compositions of the terrestrial mantle – Part 2: Mafic lithologies

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