Short-lived mafic magmatism at 560–570 Ma in the northern Norwegian Caledonides: U–Pb zircon ages from the Seiland Igneous Province

R. J. ROBERTS; F. CORFU; T. H. TORSVIK; L. D. ASHWAL; D. M. RAMSAY

doi:10.1017/S0016756806002512

Abstract

The Seiland Igneous Province (SIP) of northern Norway comprises a suite of mainly gabbroic plutons, with subordinate ultramafic, syenitic and felsic intrusions. Several intrusions from the Seiland Igneous Province have been dated by ID-TIMS U–Pb zircon and monazite analyses. The Hasvik Gabbro on the island of Sørøy, previously assigned an age of 700±33 Ma by Sm–Nd, yields a U–Pb zircon age of 562±6 Ma, within error of the Storelv Gabbro (569±5 Ma) and a diorite associated with the Breivikbotn Gabbro (571±4 Ma). Various intrusions on the Øksfjord peninsula give nearly identical ages of 565±9 Ma (gabbro), 566±4 Ma (monzonite), 565±5 Ma (monzodiorite), 570±9 Ma (norite), and 566±1 Ma (orthopyroxenite). These ages overlap with those from Sørøy, and define a single and short-lived period of gabbroic (to felsic) magmatism for the region between 570 and 560 Ma, pre-dating a subordinate episode of alkalic magmatism at 530–520 Ma. The U–Pb ages contradict the previous geochronological interpretation for the Finnmark area, which implied a period of 250 m.y. for the emplacement of the SIP intrusions. The new age data also clearly distinguish the Seiland intrusions, emplaced into the Sørøy Group metasediments of the Kalak Nappe Complex, from several older granitic intrusions (c. 850 to 600 Ma) that cut the Sørøy Group farther east and south. The coincident ages of the different Seiland intrusive bodies also contradict the previous structural model for the area, which posits that the different gabbro bodies were emplaced at intervals, with compressional deformation affecting the gabbros between periods of intrusion. The short time span between the main plutonic phases strongly suggests that the mechanism for the emplacement of mafic magma operated in a single, probably extensional, tectonic regime. The mafic intrusions were later deformed and metamorphosed to at least amphibolite facies, most likely by the Scandian (420 Ma) phase of the Caledonian Orogeny.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Kirkland, C.L. Daly, J.S. and Whitehouse, M.J. 2006. Granitic magmatism of Grenvillian and late Neoproterozoic age in Finnmark, Arctic Norway—Constraining pre-Scandian deformation in the Kalak Nappe Complex. Precambrian Research, Vol. 145, Issue. 1-2, p. 24.

Ritzmann, Oliver and Faleide, Jan Inge 2007. Caledonian basement of the western Barents Sea. Tectonics, Vol. 26, Issue. 5,

Pease, V. Daly, J.S. Elming, S.-Å. Kumpulainen, R. Moczydlowska, M. Puchkov, V. Roberts, D. Saintot, A. and Stephenson, R. 2008. Baltica in the Cryogenian, 850–630 Ma. Precambrian Research, Vol. 160, Issue. 1-2, p. 46.

Kirkland, C.L. Daly, J.S. Chew, D.M. and Page, L.M. 2008. The Finnmarkian Orogeny revisited: An isotopic investigation in eastern Finnmark, Arctic Norway. Tectonophysics, Vol. 460, Issue. 1-4, p. 158.

Kirkland, Christopher L. Whitehouse, Martin J. and Slagstad, Trond 2009. Fluid-assisted zircon and monazite growth within a shear zone: a case study from Finnmark, Arctic Norway. Contributions to Mineralogy and Petrology, Vol. 158, Issue. 5, p. 637.

Barrère, C. Ebbing, J. and Gernigon, L. 2009. Offshore prolongation of Caledonian structures and basement characterisation in the western Barents Sea from geophysical modelling. Tectonophysics, Vol. 470, Issue. 1-2, p. 71.

Marello, Laura Ebbing, Jörg and Gernigon, Laurent 2010. Magnetic basement study in the Barents Sea from inversion and forward modelling. Tectonophysics, Vol. 493, Issue. 1-2, p. 153.

Filatova, N. I. and Khain, V. E. 2010. The Arctida Craton and Neoproterozoic-Mesozoic orogenic belts of the Circum-Polar region. Geotectonics, Vol. 44, Issue. 3, p. 203.

Roberts, R.J. Corfu, F. Torsvik, T.H. Hetherington, C.J. and Ashwal, L.D. 2010. Age of alkaline rocks in the Seiland Igneous Province, Northern Norway. Journal of the Geological Society, Vol. 167, Issue. 1, p. 71.

Barrère, C. Ebbing, J. and Gernigon, L. 2011. 3-D density and magnetic crustal characterization of the southwestern Barents Shelf: implications for the offshore prolongation of the Norwegian Caledonides. Geophysical Journal International, Vol. 184, Issue. 3, p. 1147.

Werner, Stephanie C. Ebbing, Jörg Litvinova, Tamara P. and Olesen, Odleiv 2011. Chapter 11 Structural interpretation of the Barents and Kara Seas from gravity and magnetic data. Geological Society, London, Memoirs, Vol. 35, Issue. 1, p. 197.

Kirkland, C.L. Bingen, B. Whitehouse, M.J. Beyer, E. and Griffin, W.L. 2011. Neoproterozoic palaeogeography in the North Atlantic Region: Inferences from the Akkajaure and Seve Nappes of the Scandinavian Caledonides. Precambrian Research, Vol. 186, Issue. 1-4, p. 127.

Bingen, B. Belousova, E.A. and Griffin, W.L. 2011. Neoproterozoic recycling of the Sveconorwegian orogenic belt: Detrital-zircon data from the Sparagmite basins in the Scandinavian Caledonides. Precambrian Research, Vol. 189, Issue. 3-4, p. 347.

Menegon, Luca Nasipuri, Pritam Stünitz, Holger Behrens, Harald and Ravna, Erling 2011. Dry and strong quartz during deformation of the lower crust in the presence of melt. Journal of Geophysical Research, Vol. 116, Issue. B10,

Fettes, D.J. Macdonald, R. Fitton, J.G. Stephenson, D. and Cooper, M.R. 2011. Geochemical evolution of Dalradian metavolcanic rocks: implications for the break-up of the Rodinia supercontinent. Journal of the Geological Society, Vol. 168, Issue. 5, p. 1133.

Davis, William J. Corfu, F. Gerber, M. Andersen, T. B. Torsvik, T. H. and Ashwal, L. D. 2011. Age and significance of Grenvillian and Silurian orogenic events in the Finnmarkian Caledonides, northern NorwayThis article is one of a series of papers published in this Special Issue on the theme of Geochronology in honour of Tom Krogh.. Canadian Journal of Earth Sciences, Vol. 48, Issue. 2, p. 419.

LORENZ, HENNING GEE, DAVID G. LARIONOV, ALEXANDER N. and MAJKA, JAROSLAW 2012. The Grenville–Sveconorwegian orogen in the high Arctic. Geological Magazine, Vol. 149, Issue. 5, p. 875.

Dill, Harald G. Weber, Berthold and Klosa, Detlev 2012. Morphology and mineral chemistry of monazite–zircon-bearing stream sediments of continental placer deposits (SE Germany): Ore guide and provenance marker. Journal of Geochemical Exploration, Vol. 112, Issue. , p. 322.

Skublov, S. G. Myskova, T. A. Marin, Yu. B. Astaf’ev, B. Yu. Bogomolov, E. S. and L’vov, P. A. 2013. Geochemistry of zircon rims with different ages in gneisses of the Kola Series (SIMS, SHRIMP-II) and the problem of early caledonian thermal activization of the Kola craton. Doklady Earth Sciences, Vol. 453, Issue. 2, p. 1250.

Harald Dill, G. and Khishigsuren, S. 2013. Mineralogy of Sn–W–As–Pb–Zn–Cu-bearing alteration zones in intracontinental rare metal granites (Central Mongolia). Applied Earth Science, Vol. 122, Issue. 2, p. 97.

Download full list

Article contents

Short-lived mafic magmatism at 560–570 Ma in the northern Norwegian Caledonides: U–Pb zircon ages from the Seiland Igneous Province

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Short-lived mafic magmatism at 560–570 Ma in the northern Norwegian Caledonides: U–Pb zircon ages from the Seiland Igneous Province

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests