Radioisotopic dating of volcanic minerals is a powerful method for establishing absolute time constraints in sedimentary basins, which improves our understanding of the chronostratigraphy and evolution of basin processes. The relative plate motions of Greenland, North America, and Eurasia changed several times during the Palaeogene. However, the timing of a key part of this sequence, namely the initiation of compression between Greenland and Svalbard, is currently poorly constrained. The formation of the Central Basin in Spitsbergen is inherently linked to changes in regional plate motions, so an improved chronostratigraphy of the sedimentary sequence is warranted. Here we present U-Pb zircon dates from tephra layers close to the basal unconformity, which yield a weighted-mean 206Pb/238U age of 61.596 ± 0.028 Ma (2σ). We calculate that sustained sedimentation began at ~61.8 Ma in the eastern Central Basin based on a sediment accumulation rate of 71.6 ± 7.6 m/Myr. The timing of basin formation is broadly coeval with depositional changes at the Danian-Selandian boundary around the other margins of Greenland, including the North Sea, implying a common tectonic driving force. Furthermore, these stratigraphic tie points place age constraints on regional plate reorganization events, such as the onset of seafloor spreading in the Labrador Sea.
The onset of compression between Greenland and Svalbard in the Palaeocene led to the eventual formation of the West Spitsbergen fold-and-thrust belt in the Eocene, with a rapidly subsiding foreland basin forming adjacent to the mountain range1,2,3 (Fig. 1). The Central Basin is of particular interest because the timing of the basin’s formation is inherently linked to the evolution of regional tectonics and the relative motions of North America, Greenland, and Eurasia, which changed significantly during the Palaeogene4. The basin infill is named the Van Mijenfjorden Group; a 2.3 km thick succession subdivided into seven formations and one subgroup5 that are predominantly sandstones and siliciclastic mudstones deposited in fluvial, deltaic, and marine shelf environments6 (Fig. 1). The West Spitsbergen fold-and-thrust belt is part of a larger complex across northern Greenland and Ellesmere Island that constitutes Eurekan deformation (~53–34 Ma)3, 7. Subsidence in the Central Basin began before the formation of the fold-and-thrust belt and with no clear hiatus in sediment deposition. Therefore, a detailed understanding of the basin stratigraphy can be used to refine the chronology of plate reconfigurations in the run up to the Eurekan deformation and the opening of the northeast Atlantic.
Constraining the temporal evolution of the Central Basin is complicated by the scarcity of age-specific fauna and flora in the sedimentary record8 and a paucity of radioisotopic dates. The basin’s enclosed nature during the Palaeocene and early Eocene led to low salinity and locally low oxygen conditions, resulting in water column stratification with high carbonate corrosivity6. Biostratigraphic comparisons with global datasets are hampered by the distinct Boreal biogeographic province in the Arctic due to limited deep water connections to other oceans9. Radioisotopic dating of tephra layers in the Palaeocene Central Basin strata is limited. A 206Pb/238U age of 55.785 ± 0.086 Ma was obtained from a tephra horizon within the early Eocene Frysjaodden Formation10, the fourth formation within the Van Mijenfjorden Group5 (Fig. 1). This layer provides the basis for anchoring local cyclostratigraphic age models and the timing and duration of the Palaeocene-Eocene Thermal Maximum (PETM)10. The two lowermost formations (Firkanten and Basilika; Fig. 1) contain numerous bentonite (altered tephra) layers that could potentially be used for radioisotopic dating. Previous investigations that attempted to obtain radioisotopic ages for the Basilika formation found only detrital/inherited zircon grains, despite analysing a total of 430 zircons from four bentonite horizons11. The lack of accurate depositional ages, coupled with the importance of this location in constraining the first sustained compression between Greenland and Svalbard, highlights the need for an improved geochronology of the Central Basin.
Euhedral, core-free (optically inspected) zircon crystals interpreted to be of magmatic origin were isolated from four bentonite layers within the Firkanten and Basilika formations; three from separate borehole cores and one from an outcrop inside the Svea coal mine (Fig. 1). Single zircon crystals were dated by the U-Pb isotope dilution thermal ionization mass spectrometry technique (ID-TIMS; see Methods Section). Individual dates and weighted-mean 206Pb/238U ages are shown in Fig. 2, with data presented in Table 1. The core abbreviations are described in Figs 1 and 3. Three of the dated horizons (Bk1, Lk1, SvN) and samples Am1 and Lj1 are from a prominent ash layer located between 7.1 and 11.7 m above the regional Lower Cretaceous-Palaeocene low-angle (0.5–1°)5 unconformity (Fig. 3). Weighted-mean 206Pb/238U ages for the three samples are between 61.693 ± 0.082 Ma and 61.583 ± 0.074 Ma (2σ; including uncertainties in tracer calibrations but excluding decay constant errors). Outcrop evidence from within the Svea mine and in the field strongly suggests that these samples are from the same laterally continuous bentonite horizon that represented a large single eruption12. This is corroborated by matching geochemical signatures between samples despite extensive alteration13. The bentonite is not present in all cores in the basin, likely due to subsequent reworking that led to the erosion of tephra from palaeo-topographic highs12. However, close inspection of sedimentary structures within each bentonite layer shows no evidence of a hiatus in deposition, nor variations in chemistry from base to top13. This indicates that any reworking of material occurred soon after deposition and it is therefore extremely likely that these layers represent a single source. Assuming that the three samples (Bk1, Lk1, SvN) are equivalent, combining these analyses yields a weighted-mean 206Pb/238U age of 61.596 ± 0.028 Ma (Fig. 2). As with previous studies11, tephra horizons from the Basilika Formation were dominated by detrital grains. Only one sample (Dz2) was found to contain Palaeocene zircons, with a weighted mean 206Pb/238U age of 59.32 ± 0.19 Ma (Fig. 2). This layer is 203.8 m above the unconformity and 73.7 m above the Firkanten-Basilika boundary (a change from sandstone-dominated to shale-dominated deposition5). The lower precision on the age of this bentonite is partly due to the smaller grain size of zircons (<90 µm; zircons from the basal tephra are ~150–200 µm).
Previous investigations have established that the bentonites from the Firkanten and Basilika formations originated from at least two alkaline volcanic sources that are a likely product of continental rifting11, 13. Samples from the basal tephra layer are chemically distinct from all later ashes found in the cores, displaying overall REE enrichment with respect to chondrite, a moderate enrichment in LREE compared to HREE, and pronounced negative Ti, P, and Eu anomalies13. Full details of the geochemical fingerprinting of these tephra layers are presented in a previous study13. These chemical signatures closely match the ignimbrites and lavas of the Kap Washington Group in North Greenland14, indicating that this series is the most likely source (Fig. 4). The U-Pb ages determined herein are within the range of U-Pb ages derived from Kap Washington exposures (71–61 Ma)15, suggesting that this horizon likely represents one of the later explosive eruptions from this volcanic group. The close proximity of the tephra layer to the basal unconformity (7.1–11.7 m) corroborates the hypothesis that the cessation of Kap Washington volcanism was broadly contemporaneous with the formation of the Central Basin16.
The younger bentonites in the Firkanten and Basilika formations also display strong REE enrichment compared to chondrite, but display a strong enrichment of LREE compared to HREE and have little to no Eu anomalies (Fig. 4)13. These distinctive rare earth chemical signatures are comparable to volcaniclastic deposits in Ellesmere Island of suspected Nares Strait origin17, which suggests that the most likely source volcanoes of the younger suite of Svalbard tephras originated from the Nares Strait17, 18. None of the tephra layers studied here match the compositions of North Atlantic Igneous Province (NAIP) deposits from either West or East Greenland during the first phase of NAIP activity in the Palaeocene (Fig. 4)19, 20, negating this activity as a possible source. However, other unidentified sources proximal to the Arctic cannot be discounted for some layers11. Volcaniclastic deposits of suspected Nares Strait origin have been dated via 40Ar/39Ar to 61–58 Ma17, in agreement with the U-Pb age obtained here. There is no apparent temporal overlap of explosive activity between the two alkaline suites preserved in the Central Basin, with between 40 to 125 m of sediment between the lowermost Firkanten ash and the first appearance of the second group of bentonites in the studied cores13 (Fig. 3).
Radioisotopic dates from the Firkanten and Basilika formations, coupled with an U-Pb age from the Frysjaodden Formation10, allows us to estimate sediment accumulation rates. A cross-section across the region shows that the thickness of each formation increases westwards and southwards (Fig. 3). The prominent lowermost bentonite found in the eastern cores is absent from the western cores studied13, negating the possibility of correlating across all parts of the basin. Cross-section correlations using the new and published10 ages give an integrated sediment accumulation rate of 71.6 ± 7.6 m/Myr for the Firkanten and Basilika formations at Liljevalchfjellet after compaction (Fig. 3). The estimated mean sediment accumulation rate between the dated Basilika layer and the previously dated Frysjaodden bentonite10 is 90.9 ± 7.7 m/Myr at Liljevalchfjellet after compaction (Fig. 3). These errors include radioisotopic analytical uncertainties, coupled with errors associated with comparing different formation thicknesses between cores.
Extrapolated sediment accumulation rates allow for an estimation of first deposition in the eastern Central Basin. The first Palaeocene sediment deposition on the Cretaceous peneplain was the Grønfjorden bed, a conglomerate that is thought to represent braided river deposits in low-relief ridge and valley systems21. The Grønfjorden bed thickens to the southwest, which combined with the dominant source of clastic infill from the east11, 22, and the initiation of sedimentation in new areas in step-wise fashion during major transgressions23, strongly suggest the basal unconformity is not isochronal. Field, mine, and core examination indicates a shallow cross cutting relationship between the lowermost bentonite and the prominent Svea coal seam, indicating that the coal deposition was slightly diachronous with a northward migration of the swamps and peat mires through time12, 13. The bentonite is located 3.5 to 6.6 m above the coal seam in the area considered but is found below the coal seam in cores further north12. If it is assumed that the calculated sedimentation rate for the Firkanten formation is the same below the lowermost bentonite, then extrapolation allows us to infer that the first sediment deposition at Liljevalchfjellet is calculated to be 61.76 ± 0.09 Ma (using the same error propagation described above). However, given the difference in lithologies below (largely conglomerate and coal) and above (delta plain clastic sediments) the lowermost bentonite, the compaction of peat mires to form coal beds, and lithological evidence that deposition began southwest of the area studied, the timing of first deposition in the Central Basin began earlier than this estimate. What can be concluded with some certainty is that the lowermost bentonite is broadly coeval with the beginning of sustained and increasingly rapid subsidence in response to compression between Greenland and Svalbard.
The radioisotopic dating of bentonites from the Central Basin allow for an improved understanding of the first Palaeocene compressional motion between Greenland and Svalbard in the ‘pre-Eurekan deformation’ stage3 (Fig. 5). The onset of sustained basin formation began around 61.8 Ma, signalling the initiation of compression along the northern Greenland margin that evolved into the ‘Eurekan Stage 1′ deformational event by the Eocene3, 24. Geochemical evidence indicates that shortly after this plate restructuring there was a shift in the locus of volcanism13, 16 (Fig. 5), with explosive eruptions ceasing at Kap Washington around 61.6 Ma and starting at the Nares Strait around 61 Ma17. The age of the lowermost bentonites in the Central Basin (61.596 ± 0.028 Ma), the likely product of one of the final explosive eruptions from the Kap Washington Group, overlap with the age of the Danian-Selandian boundary (Fig. 2). The stage transition has an astronomically calibrated age of 61.607 ± 0.040 Ma25. The boundary marks a change to the deformation style within the Eurasian Plate26, the termination of 40 million years of carbonate deposition in the North Sea basin, and a shift to siliciclastic deposition related to the uplift and erosion of the Scotland-Shetland area27.
In a rigid plate framework, a defined plate boundary between Greenland and Eurasia is traditionally applied at the time of breakup and seafloor spreading, around chron C24N (e.g. refs 28, 29). The time period between C25N and C24N is also a well-documented change in seafloor spreading direction in the Labrador Sea30, 31. However, the North Atlantic has experienced a prolonged history of intermittent extension and basin formation events including late Paleozoic-Triassic, Late Jurassic- Early/Mid Cretaceous and Late Cretaceous-Paleocene times32. Therefore the implications of rifting and seafloor spreading on the opposite side of Greenland, in the Labrador Sea and Baffin Bay, renders the northern margin of Greenland a unique tectonic setting with implied relative plate motion, or deforming boundaries. Nonetheless, the synchronicity of sustained compression between Greenland and Svalbard with tectonic changes further south along the Greenland-Eurasia margin, including uplift of the Scotland-Shetland area27 and widespread shear deformation33, indicates a common driving force affecting all margins of Greenland (Fig. 5).
Several triggers for the stress changes at the Danian-Selandian boundary have been proposed, including the first pulse of magmatism from the NAIP34 and the propagation and acceleration of seafloor spreading in the Labrador Sea and Baffin Bay30, 31, 35. However, the timings of these broadly contemporaneous events are poorly constrained, and the relative contributions of plate motion driving forces remain contentious. The first phase of magmatism from the NAIP appeared in both West and East Greenland around 62 Ma34, yet the degree to which this pulse of magmatism is related to changes in plate motions is unresolved. Dating seafloor spreading in the Labrador Sea and Baffin Bay is complicated by breakup volcanism, variable sediment cover, and an unclear transition between continental and oceanic crust. Intraplate rifting in the Labrador Sea probably started in the late Jurassic36, yet the first identifiable unequivocal marine magnetic anomalies are C27 in the Labrador Sea30 (63.5–62.2 Ma37; summary in ref. 38). This led to motion of Greenland around 100 km to the ENE relative to North America30 and is therefore likely to be linked to both the deformation on the eastern margin of Greenland and the onset of compression between Greenland and Svalbard.
Most published stage poles for Greenland30, 31, 39, 40 inherently predict right-lateral motion between Greenland and Svalbard for the period between C27N-C26N or C27N-C25N (Fig. 5). However, some models30, 31, 33 also include a distinct period of Palaeocene transpression to compression between Greenland and Svalbard that fits broadly with our time period. Our chronostratigraphic data suggests that stage rotations should be revisited in the context of restoring all margins of Palaeocene Greenland, including the evidence for the onset and duration of the Central Basin formation. Choices in timescale, in particular the dating of chrons C27, C26, and C25, as well as the rotations for North America and Eurasia, are integral to consistently deciphering the regional kinematics. Our new age date of 61.8–61.6 Ma for the onset of sustained deposition in the Central Basin provides a key radio-isotopic constraint for refining regional plate kinematic models and the onset of compression between Greenland and Svalbard.
Bentonite samples were collected from a selection of borehole cores at the core facility of the Store Norske Spitsbergen Grubekompani (SNSG) in Longyearbyen and from in situ samples from within the Svea coal mine (Fig. 1). These samples have the advantage of less alteration than surface outcrops and have been logged to <1 m detail by SNSG. The samples are the same as those used in a previous study for the geochemical characterisation of tephra layers13, and the reader is referred to that paper for full details of the cores. Each bentonite is labelled with a borehole name (e.g. ‘Am’ for Amelnryggen), followed by a number based on the position of the ash in that core (‘Am1’ is the lowermost layer present). This research focussed on bentonites proximal to core BH9/2005 at Urdkollen (Ur), which has been the focus of several previous studies8, 10, 41,42,43. Sample ‘Bk1’ from Bolterskaret core BH5-2006 is located 7.5 m above the base of the Firkanten Formation, the first formation of the Van Mijenforden Group that overlies the Lower Cretaceous-Palaeocene regional unconformity. Sample ‘Lk1’ from Lunckefjellet core BH14-2012 is 7.1 m above Firkanten base, while sample ‘SvN’ is equivalent to sample ‘Am1’ as the bentonite layer can be traced between both localities within the coal mine, which is 9.2 m above the formation base. Field outcrop evidence show that these three dated samples are the same layer as sample ‘Lj1’ in the Liljevalchfjellet core (BH1-2006) 11.8 m above the unconformity, allowing this core to be used as the basis of a cross-section.
Bentonite samples were mechanically disaggregated and heavy minerals were separated using standard magnetic and heavy liquid techniques at the University of Oslo (UiO) and at the Massachusetts Institute of Technology (MIT). Zircons were selected under an optical microscope, annealed for ca. 72 hours at ca. 900 °C and chemically abraded with HF at ca. 195 °C for 14 hours44. The zircons grains chosen for analyses were spiked with a mixed 202Pb-205Pb-235U tracer (Oslo) that has recently been calibrated to the EARTHTIME (ET) 100 Ma solution45, to allow direct comparison with ages obtained with the ET2535 tracer solution46 (www.earth-time.org) that was used at MIT. After spiking, the zircons were dissolved in HF (+HNO3) at ca. 195 °C for 5 days (UiO) and at ca. 210 °C for 48 hours (MIT). Chemical separation47 was done for most grains. Details of the mass spectrometric techniques used are presented in detail in previous articles48, 49. The raw data were reduced using Tripoli50 and analytical errors and corrections (including Th-corrections, assuming Th/U in the magma of 3) were incorporated and propagated using an Excel macro and ET_Redux based on published algorithms51, 52. Ages were calculated using ISOPLOT53 and with specified decay constants54.
Steel, R., Gjelberg, J., Noettvedt, A., Helland-Hansen, W. & Kleinspehn, K. The Tertiary strike-slip basins and orogenic belt of Spitsbergen. Soc. Econ. Paleontol. Mineral. Spec. Publ. 37, 339–359 (1985).
Müller, R. & Spielhagen, R. Evolution of the Central Tertiary Basin of Spitsbergen: towards a synthesis of sediment and plate tectonic history. Palaeogeography Palaeoclimatology Palaeoecology 80, 153–172 (1990).
Piepjohn, K., von Gosen, W. & Tessensohn, F. The Eurekan deformation in the Arctic: an outline. Journal of the Geological Society 173, 1007–1024, doi:10.1144/jgs2016-081 (2016).
Kristoffersen, Y. Sea-floor spreading and the early opening of the North Atlantic. Earth and Planetary Science Letters 38, 273–290 (1978).
Dallmann, W., Midbø, P., Nøttvedt, A. & Steel, R. In Lithostratigraphic lexicon of Svalbard. (ed. W. K. Dallmann) 215–263 (Norwegian Polar Institute, 1999).
Nagy, J., Jargvoll, D., Dypvik, H., Jochmann, M. & Riber, L. Environmental changes during the Paleocene-Eocene Thermal Maximum in Spitsbergen as reflected by benthic foraminifera. Polar Research 32, 19737, doi:10.3402/polar.v32i0.19737 (2013).
Svennevig, K., Guarnieri, P. & Stemmerik, L. Tectonic inversion in the Wandel Sea Basin: A new structural model of Kilen (eastern North Greenland). Tectonics 35, 2896–2917, doi:10.1002/2016TC004152 (2016).
Harding, I. et al. Sea level and salinity fluctuations during the Palaeocene-Eocene Thermal Maximum in Arctic Spitsbergen. Earth and Planetary Science Letters 303, 97–107 (2011).
Ogawa, Y., Takahashi, K., Yamanaka, T. & Onodera, J. Significance of euxinic conditions in the middle Eocene paleo-Arctic basin: a geochemical study of the IO Arctic Coring Expedition 302 sediments. Earth and Planetary Science Letters 285, 190–197 (2009).
Charles, A. et al. Constraints on the numerical age of the Palaeocene-Eocene boundary. Geochemistry, Geophysics, Geosystems 12, Q0AA17, doi:10.1029/2010GC003426 (2011).
Elling, F. J. et al. Origin of Bentonites and Detrital Zircons of the Paleocene Basilika Formation, Svalbard. Frontiers in Earth Science 4, doi:10.3389/feart.2016.00073 (2016).
Marshall, C. Palaeogeographic development and economic potential of the coal-bearing Palaeocene Todalen member, Spitsbergen PhD thesis, University of Nottingham, (2013).
Jones, M. T. et al. Palaeocene magmatism and rifting events in the North Atlantic-Arctic Oceans constrained by geochemistry of bentonites from Svalbard. Journal of Volcanology and Geothermal Research 327, 571–584, doi:10.1016/j.jvolgeores.2016.09.014 (2016).
Thorarinsson, S., Holm, P., Duprat, H. & Tegner, C. Petrology and Sr-Nd-Pb isotope geochemistry of the Late Cretaceous continental rift ignimbrites, Kap Washington peninsula, North Greenland. Journal of Volcanology and Geothermal Research 219–220, 63–86 (2012).
Thorarinsson, S., Holm, P., Tappe, S., Heaman, L. & Tegner, C. Late Cretaceous-Palaeocene continental rifting in the High Arctic: U-Pb geochronology of the Kap Washington Group volcanic sequence, North Greenland. Journal of the Geological Society, London 168, 1093–1106 (2011).
Tegner, C. et al. Magmatism and Eurekan deformation in the High Arctic Large Igneous Province: 40Ar-39Ar age of Kap Washington Group volcanics, North Greenland. Earth and Planetary Science Letters 303, 203–214 (2011).
Estrada, S., Henjes-Kunst, F., Melcher, F. & Tessensohn, F. Palaeocene alkaline volcanism in the Nares Strait region: evidence from volcanic pebbles. International Journal of Earth Sciences 99, 863–890 (2010).
Reinhardt, L. et al. Altered volcanic ashes in Palaeocene and Eocene sediments of the Eureka Sound Group (Ellesmere Island, Nunavut, Arctic Canada). Zeitschrift der deutschen Gesellschaft für Geowissenschaften 164, 131–147 (2013).
Hansen, H. et al. in The North Atlantic Igneous Province: Stratigraphy, Tectonic, Volcanic and Magmatic Processes Vol. 197 (eds D. W. Jolley & B. R. Bell) 183–218 (Geological Society, London, Special Publications, 2002).
Larsen, L. M. & Pedersen, A. K. Petrology of the Paleocene Picrites and Flood Basalts on Disko and Nuussuaq, West Greenland. Journal of Petrology 50, 1667–1711 (2009). doi:0.1093/petrology/egp048.
Nagy, J. Delta-influenced foraminiferal facies and sequence stratigraphy of Paleocene deposits in Spitsbergen. Palaeogeography Palaeoclimatology Palaeoecology 222, 161–179 (2005).
Bruhn, R. & Steel, R. High-resolution sequence stratigraphy of a clastic foredeep succession (Paleocene, Spitsbergen): An example of peripheral-bulge-controlled depositional architecture. Journal of Sedimentary Research 73, 745–755 (2003).
Lüthje, C. J. Transgressive Development of Coal-bearing Coastal Plain to Shallow Marine Setting in a Flexural Compressional Basin, Paleocene, Svalbard, Arctic Norway PhD thesis, University of Bergen, (2008).
Piepjohn, K., von Gosen, W., Läufer, A., McClelland, W. C. & Estrada, S. Ellesmerian and Eurekan fault tectonics at the northern margin of Ellesmere Island (Canadian High Arctic) [Ellesmerische und Eurekan-Störungstektonik am Nordrand von Ellesmere Island (kanadische Hocharktis).]. Zeitschrift der Deutschen Gesellschaft für Geowissenschaften 164, 81–105, doi:10.1127/1860-1804/2013/0007 (2013).
Dinarès-Turell, J., Westerhold, T., Pujalte, V., Röhl, U. & Kroon, D. Astronomical calibration of the Danian stage (Early Paleocene) revisited: Settling chronologies of sedimentary records across the Atlantic and Pacific Oceans. Earth and Planetary Science Letters 405, 119–131, doi:10.1016/j.epsl.2014.08.027 (2014).
Nielsen, S. & Stephenson, R. & Thomsen. Dynamics of Mid-Palaeocene North Atlantic rifting linked with European intra-plate deformations. Nature 450, 1071–1074, doi:10.1038/nature06379 (2007).
Clemmensen, A. & Thomas, E. Palaeoenvironmental changes across the Danian-Selandian boundary in the North Sea Basin. Palaeogeography Palaeoclimatology Palaeoecology 219, 351–394, doi:10.1016/j.palaeo.2005.01.005 (2005).
Srivastava, S. P. & Tapscott, C. Plate kinematics of the North Atlantic. The Geology of North America 1000, 379–404 (1986).
Gaina, C., Gernigon, L. & Ball, P. Palaeocene–Recent plate boundaries in the NE Atlantic and the formation of the Jan Mayen microcontinent. Journal of the Geological Society 166, 601–616 (2009).
Oakey, G. & Chalmers, J. A new model for the paleogene motion of Greenland relative to North America: Plate reconstructions of the Davis Strait and Nares Strait regions between Canada and Greenland. Journal of Geophysical Research - Solid Earth 117, B10401, doi:10.1029/2011JB008942 (2012).
Roest, W. R. & Srivastava, S. P. Sea-floor spreading in the Labrador Sea: A new reconstruction. Geology 17, 1000–1003 (1989).
Faleide, J. I. et al. Structure and evolution of the continental margin off Norway and the Barents Sea. Episodes 31, 82–91 (2008).
Guarnieri, P. Pre-break-up palaeostress state along the East Greenland margin. Journal of the Geological Society, London 172, 727–739, doi:10.1144/jgs2015-053 (2015).
Storey, M., Duncan, R. & Tegner, C. Timing and duration of volcanism in the North Atlantic Igneous Province: Implications for geodynamics and links to the Iceland hotspot. Chemical Geology 241, 264–281 (2007).
Srivastava, S. P. Evolution of the Labrador Sea and its bearing on the early evolution of the North Atlantic. Geophysical Journal of the Royal Astronomic Society 52, 313–357 (1978).
Larsen, L. M. Mesozoic to Palaeogene dyke swarms in West Greenland and their significance for the formation of the Labrador Sea and the Davis Strait. Rapp. Dan. Groenl. Geol. Unders. 34, 84 (2006).
Ogg, J. In The Geologic Time Scale 2012 (eds F. Gradstein, J. G. Ogg, M. D. Schmitz, & G. Ogg) 85–113 (Elsevier, 2012).
Hosseinpour, M., Müller, R., Williams, S. & Whittaker, J. Full-fit reconstruction of the Labrador Sea and Baffin Bay. Solid Earth 4, 461–479, doi:10.5194/se-4-461-2013 (2013).
Barnett-Moore, N., Müller, R., Williams, S., Skogseid, J. & Seton, M. A reconstruction of the North Atlantic since the earliest Jurassic. Basin Research 1–26, doi:10.1111/bre.12214 (2016).
Torsvik, T., Müller, R., Van der Voo, R., Steinberger, B. & Gaina, C. Global plate motion frames: Toward a unified model. Reviews of Geophysics 46, RG3004, doi:10.1029/2007RG000227 (2008).
Uroza, C. & Steel, R. A highstand shelf-margin delta system from the Eocene of west Spitsbergen, Norway. Sedimentary Geology 203, 229–245 (2008).
Cui, Y. et al. Slow release of fossil carbon during the Palaeocene–Eocene Thermal Maximum. Nature Geoscience 4, 481–485 (2011).
Dypvik, H. et al. The Paleocene-Eocene Thermal Maximum in Svalbard – clay mineral and geochemical signals. Palaeogeography Palaeoclimatology Palaeoecology 303, 156–169 (2011).
Mattinson, J. Zircon U–Pb chemical abrasion (“CA-TIMS”) method: Combined annealing and multi-step partial dissolution analysis for improved precision and accuracy of zircon ages. Chemical Geology 220, 47–66 (2005).
Svensen, H., Hammer, Ø. & Corfu, F. Astronomically forced cyclicity in the Upper Ordovician and U-Pb ages of interlayered tephra, Oslo Region, Norway. Palaeogeography Palaeoclimatology Palaeoecology 418, 150–159 (2015).
Condon, D., Schoene, B., McLean, N., Bowring, S. & Parrish, R. Metrology and Traceability of U-Pb Isotope Dilution Geochronology (EARTHTIME Tracer Calibration Part I). Geochimica et Cosmochimica Acta 164, 464–480 (2015).
Krogh, T. A low-contamination method for hydrothermal decomposition of zircon and extraction of U and Pb for isotopic age determinations. Geochimica et Cosmochimica Acta 37 (1973).
Augland, L., Andresen, A. & Corfu, F. Age, structural setting, and exhumation of the Liverpool Land eclogite terrane, East Greenland Caledonides. Lithosphere 2, 267–286 (2010).
Burgess, S., Bowring, S., Fleming, T. & Elliot, D. High-precision geochronology links the Ferrar large igneous province with early-Jurassic ocean anoxia and biotic crisis. Earth and Planetary Science Letters 415, 90–99 (2015).
Bowring, J., McLean, N. & Bowring, S. Engineering cyber infrastructure for U-Pb geochronology: Tripoli and U-Pb_Redux. Geochemistry, Geophysics, Geosystems 12, Q0AA19 (2011).
Schmitz, M. & Schoene, B. Derivation of isotope ratios, errors, and error correlations for U-Pb geochronology using 205Pb-235U-(233U)-spiked isotope dilution thermal ionization mass spectrometric data. Geochemistry, Geophysics, Geosystems 8, Q08006 (2007).
McLean, N. M., Bowring, J. F. & Bowring, S. A. An algorithm for U‐Pb isotope dilution data reduction and uncertainty propagation. Geochemistry, Geophysics, Geosystems 12, Q0AA18, doi:10.1029/2010GC003478 (2011).
Ludwig, K. ISOPLOT/Ex, A geochronological toolkit for Microsoft Excel. Berkeley Geochronology Center Special Publication 4, 70 (2003).
Jaffey, A., Flynn, K., Glendenin, L., Bentley, W. & Essling, A. Precision measurement of half-lives and specific activities of 235U and 238U. Physics Reviews C4, 1889–1906 (1971).
Major, H., Haremo, P., Dallmann, W. K. & Andresen, A. In Geological Map of Svalbard 1:100,000 Sheet C9G Adventdalen (Norsk Polarinstitutt Temakart, 2001).
Sun, S.-S. & McDonough, W. F. In Magmatism in Ocean Basins (eds A. D. Saunders & M. J. Norry) 313–345 (Geological Society, London, Special Publications, 1989).
Boyden, J. et al. In Geoinformatics: Cyberinfrastructure for the Solid Earth Sciences (eds Keller G. R. & C. Baru) 95–114 (Cambridge UNiversity Press, 2011).
Gurnis, M. et al. Plate Tectonic Reconstructions with Continuously Closing Plates. Computers and Geosciences 38, 35–42 (2012).
Shephard, G., Müller, D. & Seton, M. The tectonic evolution of the Arctic since Pangea breakup: Integrating constraints from surface geology and geophysics with mantle structure. Earth Science Reviews 124, 148–183 (2013).
Wessel, P., Smith, W., Scharroo, R., Luis, J. & Wobbe, F. Generic Mapping Tools: Improved 1542 Version Released. Eos, Transactions American Geophysical Union 94, 409–410 (2013).
Staff at Store Norske AS, Carmen Gaina, Jan Inge Faleide, Mohamed Mansour Abdelmalak, Fernando Corfu, and Gunborg Bye Fjeld are warmly thanked for their assistance. MTJ, LEA, GES, DAJ, SP and HHS are supported by the Research Council of Norway through its Centres of Excellence funding scheme, project number 223272, and MTJ and HHS by a Research Council of Norway grant (EPIC). GES acknowledges VISTA – a basic research program in collaboration between The Norwegian Academy of Science and Letters, and Statoil (Project 6268, ‘DEFMOD’).
The authors declare that they have no competing interests.
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Jones, M.T., Augland, L.E., Shephard, G.E. et al. Constraining shifts in North Atlantic plate motions during the Palaeocene by U-Pb dating of Svalbard tephra layers. Sci Rep 7, 6822 (2017). https://doi.org/10.1038/s41598-017-06170-7