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First evidence for Neoproterozoic rocks offshore South-East Greenland

Published online by Cambridge University Press:  27 January 2022

Pierpaolo Guarnieri*
Affiliation:
Geological Survey of Denmark and Greenland (GEUS), Department of Petrology and Economic Geology, Øster Voldgade 10, 1350Copenhagen, Denmark
Michael Storey
Affiliation:
Quadlab Natural History Museum of Denmark, Gothersgade 130, 1123Copenhagen, Denmark
Tonny B. Thomsen
Affiliation:
Geological Survey of Denmark and Greenland (GEUS), Department of Petrology and Economic Geology, Øster Voldgade 10, 1350Copenhagen, Denmark
Benjamin Dominguez Heredia
Affiliation:
Geological Survey of Denmark and Greenland (GEUS), Department of Petrology and Economic Geology, Øster Voldgade 10, 1350Copenhagen, Denmark
Sebastian Næsby Malkki
Affiliation:
Geological Survey of Denmark and Greenland (GEUS), Department of Petrology and Economic Geology, Øster Voldgade 10, 1350Copenhagen, Denmark
*
Author for correspondence: Pierpaolo Guarnieri, Email: pgua@geus.dk

Abstract

Meta-sedimentary rocks recovered beneath Palaeogene basalts near the base of Ocean Drilling Program (ODP) Leg 152-917A offshore South-East Greenland were thought to be of Late Cretaceous age. This interpretation, however, has several inconsistencies as it requires a tectono-metamorphic event during the Cretaceous not recognized in the North Atlantic region, and the presence of a wide Mesozoic sedimentary basin that extended from SE-Greenland to the Rockall Plateau, for which there is currently no evidence. Here, we report a Neoproterozoic U/Pb apatite age of 905 ± 21 Ma and a younger 40Ar/39Ar isochron whole-rock age of 820 ± 40 Ma for an altered tuff layer that occurs in the upper part of the meta-volcaniclastic sequence recovered from hole 917A. The 40Ar/39Ar step-heating ages on biotite and whole-rock mini-cores from deeper in hole 917A yielded Palaeoproterozic dates that cluster around 1950 to 1850 Ma, pointing toward a Palaeoproterozoic source. The U/Pb apatite date is interpreted as the eruption age of the tuff layer, whereas the younger whole-rock 40Ar/39Ar age is consistent with low-temperature greenschist alteration of volcanic glass and secondary mineral growth during sedimentary burial in an extensional regime. The c. 905 Ma age for the tuff provides the first evidence for Neoproterozoic rocks offshore South-East Greenland and suggests a correlation between this sequence and the Torridon Group in the Hebridean Foreland of the Scottish Caledonides. The calc-alkaline nature of the volcaniclastic rocks and the age of the tuff layer point toward a source area with arc-magmatism related to the Renlandian event of the Valhalla Orogeny.

Type
Original Article
Copyright
© The Author(s), 2022. Published by Cambridge University Press

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References

Batchelor, RA (2011) Geochemistry of Torridonian tuffs and contemporary phosphorites: potential for correlation of Torridonian sequences in NW Scotland. Scottish Journal of Geology 47, 133–42.CrossRefGoogle Scholar
Batchelor, RA and Prave, AR (2010) Crystal tuff in the Stoer Group, Torridonian Supergroup, NW Scotland. Scottish Journal of Geology 46, 16.CrossRefGoogle Scholar
Cawood, PA, Strachan, R, Cutts, K, Kinny, PD, Hand, M and Pisarevsky, S (2010) Neoproterozoic orogeny along the margin of Rodinia: Valhalla orogen, North Atlantic. Geology 38, 99102.CrossRefGoogle Scholar
Chew, DM, Sylvester, PJ and Tubrett, MN (2011) U-Pb and Th-Pb dating of apatite by LA-ICPMS. Chemical Geology 280, 200–16.CrossRefGoogle Scholar
Clift, PD, Carter, A and Hurford, AJ (1996) Constraints on the evolution of the East Greenland Margin: Evidence from detrital apatite in offshore sediments. Geology 24(11), 10136.2.3.CO;2>CrossRefGoogle Scholar
Demant, A, Münch, P, Romeuf, N and Morata, D (1998) Distribution and chemistry of secondary minerals (zeolites and clay minerals) from Hole 917A, Southeast Greenland margin. In Proceedings of the Ocean Drilling Program, Scientific Results, vol. 152 (eds Saunders, AD, Larsen, HC and Wise, SW , Jr), pp. 417–24.Google Scholar
Gerlings, J, Hopper, RJ, Fyhn, MBW and Frandsen, N (2017) Mesozoic and older rift basins on the SE Greenland Shelf offshore Ammassalik. In The NE Atlantic Region: A Reappraisal of Crustal Structure, Tectonostratigraphy and Magmatic Evolution (eds Péron-Pinvidic, G, Hopper, JR, Stoker, MS, Gaina, C, Doornenbal, JC, Funck, T and Árting, UE), pp. 375–92. Geological Society of London, Special Publication no. 447.Google Scholar
Hitchen, K (2004) The geology of the UK Hatton–Rockall margin. Marine and Petroleum Geology 21, 9931012.CrossRefGoogle Scholar
Hopper, JR, Funck, T, Stoker, M, Árting, U, Peron-Pindivic, G, Gaina, C and Doornenbal, H (eds) (2014) Tectonostratigraphic Atlas of the North-East Atlantic Region. Copenhagen: Geological Survey of Denmark and Greenland (GEUS).Google Scholar
Jackson, SE, Pearson, NJ, Griffin, WL and Belousova, EA (2004) The application of laser ablation-inductively coupled plasma-mass spectrometry to in situ U–Pb zircon geochronology. Chemical geology 211(1–2), 4769.CrossRefGoogle Scholar
Keulen, N, Malkki, SN and Graham, S (2020) Automated Quantitative Mineralogy applied to metamorphic rocks. Minerals 10, 47.CrossRefGoogle Scholar
Kinnaird, TC, Prave, AR, Kirkland, CL, Horstwood, M, Parrish, R and Batchelor, RA (2007) The late Mesoproterozoic–early Neoproterozoic tectonostratigraphic evolution of NW Scotland: the Torridonian revisited. Journal of the Geological Society , London 164, 541–51.CrossRefGoogle Scholar
Kolb, J (2014) Structure of the Palaeoproterozoic Nagssugtoqidian Orogen, SE Greenland: model for the tectonic evolution. Precambrian Research 225, 809–22.CrossRefGoogle Scholar
Kuiper, KF, Deino, A, Hilgen, FJ, Krijgsman, W, Renne, PR and Wijbrans, JR (2008) Synchronizing rock clocks of Earth history. Science 320, 500–4.CrossRefGoogle ScholarPubMed
Larsen, HC, Saunders, AD, Clift, PD and Shipboard Scientific Party (1994) Proceedings of the Ocean Drilling Program, Initial Reports, vol. 152. College Station, Texas.CrossRefGoogle Scholar
Larsen, HC and Saunders, AD (1998) Tectonism and volcanism at the southeast Greenland rifted margin: a record of plume impact and later continental rupture. In Proceedings of the Ocean Drilling Program, Scientific Results, vol. 152 (eds Saunders, AD, Larsen, HC and Wise, SW , Jr), pp. 503–33. College Station, Texas.Google Scholar
Larsen, M, Bell, B, Guarnieri, P, Vosgerau, P and Weibel, R (2018) Exploration challenges along the North Atlantic volcanic margins: the intra-volcanic sandstone play in subsurface and outcrop. Geological Society, London, Petroleum Geology Conference series 8, 231–45.CrossRefGoogle Scholar
Larsen, M, Hamberg, L, Olaussen, S, Nørgaard-Pedersen, N and Stemmerik, L (1999) Basin evolution in southern East Greenland: an outcrop analogue for Cretaceous–Paleogene basins in the North Atlantic volcanic margins. American Association of Petroleum Geologists Bulletin 83, 1236–61.Google Scholar
Lee, J-Y, Marti, K, Severinghaus, JP, Kawamura, K, Yoo, H-S, Lee, JB and Kim, JS (2006) A redetermination of the isotopic abundances of atmospheric Ar. Geochimica et Cosmochimica Acta 70, 4507–12.CrossRefGoogle Scholar
Leslie, AG and Nutman, AP (2003) Evidence for Neoproterozoic orogenesis and early high temperature Scandian deformation events in the southern East Greenland Caledonides. Geological Magazine 140, 309–33.CrossRefGoogle Scholar
Ludwig, KR (1998) On the treatment of concordant uranium-lead ages. Geochimica et Cosmochimica Acta 62(4), 66576.CrossRefGoogle Scholar
Nielsen, TFD, Soper, NJ, Brooks, CK, Faller, AM, Higgins, AC and Matthews, DW (1981) The Pre-Basaltic Sediments and the Lower Basalts at Kangerdlugssuaq, East Greenland: their stratigraphy, lithology, palaeomagnetism and petrology. Meddelelser om Grønland Geoscience 6.Google Scholar
Petrus, JA and Kamber, BS (2012) VizualAge: A novel approach to laser ablation ICP‐MS U‐Pb geochronology data reduction. Geostandards and Geoanalytical Research 36(3), 24770.CrossRefGoogle Scholar
Paton, C, Woodhead, JD, Hellstrom, JC, Hergt, JM, Greig, A and Maas, R (2010) Improved laser ablation U‐Pb zircon geochronology through robust downhole fractionation correction. Geochemistry, Geophysics, Geosystems 11(3).CrossRefGoogle Scholar
Paton, C, Hellstrom, J, Paul, B, Woodhead, J and Hergt, J (2011) Iolite: Freeware for the visualisation and processing of mass spectrometric data. Journal of Analytical Atomic Spectrometry 26, 250818.CrossRefGoogle Scholar
Rivera, TA, Storey, M, Zeeden, C, Hilgen, FJ and Kuiper, K (2011) A refined astronomically calibrated 40Ar/39Ar age for Fish Canyon sanidine. Earth and Planetary Science Letters 311, 420–6.CrossRefGoogle Scholar
Schoene, B and Bowring, S (2006) U-Pb systematics of the McClure Mountain syenite: thermochronological constraints on the age of the 40Ar/39Ar standard MMhb. Contributions to Mineralogy and Petrology 151, 615–30.CrossRefGoogle Scholar
Sláma, J, Košler, J, Condon, DJ, Crowley, JL, Gerdes, A, Hanchar, JM, Horstwood, MSA, Morris, GA, Nasdala, L, Norberg, N, Schaltegger, U, Schoene, B, Tubrett, MN and Whitehouse, MJ (2008) Plešovice zircon—a new natural reference material for U–Pb and Hf isotopic microanalysis. Chemical Geology 249(1–2), 135.CrossRefGoogle Scholar
Soper, NJ, Higgins, AC, Matthews, DW and Brown, PE (1976) Late Cretaceous – early Tertiary stratigraphy of the Kangerdlugssuaq area, east Greenland, and the age of the opening of the north-east Atlantic. Journal of the Geological Society, London 132, 85104.CrossRefGoogle Scholar
Spencer, CJ, Kirkland, CL, Prave, AR, Strachan, RA and Pease, V (2019) Crustal reworking and orogenic styles inferred from zircon Hf isotopes: Proterozoic examples from the North Atlantic region. Geoscience Frontiers 10, 417–24. doi:10.1016/j.gsf.2018.09.008.CrossRefGoogle Scholar
Stacey, JT and Kramers, JD (1975) Approximation of terrestrial lead isotope evolution by a two-stage model. Earth and planetary science letters 26(2), 20721.CrossRefGoogle Scholar
Storey, M, Duncan, RA and Swisher, CC (2007) Paleocene-Eocene thermal maximum and the opening of the northeast Atlantic. Science 316, 587–9.CrossRefGoogle ScholarPubMed
Tegner, C, Duncan, RA, Bernstein, S, Brooks, CK, Bird, DK and Storey, M (1998) Ar-40-Ar-39 geochronology of Tertiary mafic intrusions along the East Greenland rifted margin: relation to flood basalts and the Iceland hotspot track. Earth and Planetary Science Letters 156, 7588.CrossRefGoogle Scholar
Tera, F and Wasserburg, GJ (1972) U-Th-Pb systematics in three Apollo 14 basalts and the problem of initial Pb in lunar rocks. Earth and Planetary Science Letters 14(3), 281304.CrossRefGoogle Scholar
Turnbull, MJM, Whitehouse, MJ and Moorbath, S (1996) New isotopic age determinations for the Torridonian, NW Scotland. Journal of the Geological Society of London 153, 955–64.CrossRefGoogle Scholar
Vallier, T, Calk, L, Stax, R and Demant, A (1998) Metamorphosed sedimentary (volcaniclastic?) rocks beneath Paleocene Basalt in Hole 917A, East Greenland margin. In Proceedings of the Ocean Drilling Program, Scientific Results, vol. 152 (eds Saunders, AD, Larsen, HC, and Wise, SW , Jr), pp. 129–44, College Station, Texas.Google Scholar
Verati, C and Jourdan, F (2014) Modelling effect of sericitization of plagioclase on the 40K/40Ar and 40Ar/39Ar chronometers: implication for dating basaltic rocks and mineral deposits. In Advances in 40 Ar/ 39 Ar Dating: From Archaeology to Planetary Sciences (eds F Jourdan, DF Mark and C Verati), pp. 155–74. Geological Society of London, Special Publication no. 378.CrossRefGoogle Scholar
Vermeesch, P (2018) IsoplotR: a free and open toolbox for geochronology. Geoscience Frontiers 9, 1479–93.CrossRefGoogle Scholar
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