Hostname: page-component-586b7cd67f-dsjbd Total loading time: 0 Render date: 2024-11-28T00:04:30.472Z Has data issue: false hasContentIssue false
  • English
  • Français

Understanding the offshore flood basalt sequence using onshore volcanic facies analogues: an example from the Faroe–Shetland basin

Published online by Cambridge University Press:  23 February 2009

DOUGAL A. JERRAM ,
RICHARD T. SINGLE ,
RICHARD W. HOBBS  and
CATHERINE E. NELSON
DOUGAL A. JERRAM*
Affiliation:
Department of Earth Sciences, The University of Durham, South Rd, Durham DH1 3LE, UK
RICHARD T. SINGLE
Affiliation:
Department of Earth Sciences, The University of Durham, South Rd, Durham DH1 3LE, UK
RICHARD W. HOBBS
Affiliation:
Department of Earth Sciences, The University of Durham, South Rd, Durham DH1 3LE, UK
CATHERINE E. NELSON
Affiliation:
Department of Earth Sciences, The University of Durham, South Rd, Durham DH1 3LE, UK
*
Author for correspondence: [email protected]
Get access Rights & Permissions [Opens in a new window]

Abstract

Flood basalts in associated volcanic rifted margins, such as the North Atlantic Igneous Province, have a significant component of lavas which are preserved in the present day in an offshore setting. A close inspection of the internal facies architecture of flood basalts onshore provides a framework to interpret the offshore sequences imaged by remote techniques such as reflection seismology. A geological interpretation of the offshore lava sequences in the Faroe–Shetland Basin, using constraints from onshore analogues such as the Faroe Islands, allows for the identification of a series of lava sequences which have characteristic properties so that they can be grouped. These are tabular simple flows, compound-braided flows, and sub-aqueously deposited hyaloclastite facies. The succession of volcanic rocks calculated in this study has a maximum thickness in excess of 6800 m. Down to the top of the sub-volcanic sediments, the offshore volcanic succession has a thickness of about 2700 m where it can be clearly identified across much of the area, with a further 2700 m or more of volcanic rock estimated from the combined gravity and seismic modelling to the north and west of the region. A large palaeo-waterbody is identified on the basis of a hyaloclastite front/apron consisting of a series of clinoforms prograding towards the eastern part of the basin. This body was > 500 m deep, must have been present at the onset of volcanism into this region, and parts of the water body would have been present during the continued stages of volcanism as indicated by the distribution of the hyaloclastite apron.

Keywords

British TertiaryLIPhyaloclastitelava sequences
Type
Original Article
Information
Geological Magazine , Volume 146 , Issue 3 , May 2009 , pp. 353 - 367
Copyright
Copyright © Cambridge University Press 2009

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

Footnotes

Present address: Senior Geologist, Det norske oljeselskap ASA, P.O. Box 2070 Vika, NO-0125 Oslo, Norway

References

Boldreel, L. O. 2006. Wireline log-based stratigraphy of flood basalts from the Lopra-1/1A well, Faroe Islands. In Scientific results from the deepened Lopra-1 borehole, Faroe Islands (eds Chalmers, J. A. & Waagstein, R.), pp. 7–22. Geological Survey of Denmark and Greenland Bulletin 9.Google Scholar
Boldreel, L. O. & Andersen, M. S. 1993. Late Palaeocene to Miocene compression in the Faroes-Rockall area. In Petroleum Geology of Northwest Europe: Proceedings of the 4th Conference (ed. Parker, J. R.), pp. 1025–34. Geological Society of London.Google Scholar
Davies, R., Cloke, I., Cartwright, J., Robinson, A. & Ferrero, C. 2004. Post-breakup compression of a passive margin and its impact on hydrocarbon prospectivity: An example from the Tertiary of the Faeroe–Shetland Basin, United Kingdom. American Association of Petroleum Geologists Bulletin 88 (1), 120.CrossRefGoogle Scholar
Duncan, A. R., Newton, S. R., Van Den Berg, C. & Reid, D. L. 1989. Geochemistry and petrology of dolerite sills in the Huab River valley, Damaraland, north-western Namibia. Communications of the Geological Survey of Namibia 5, 517.Google Scholar
Eldholm, O. & Grue, K. 1994. North Atlantic volcanic margins: dimensions and production rates. Journal of Geophysical Research 99, 2955–68.CrossRefGoogle Scholar
Eldholm, O., Thiede, J. & Taylor, E. 1987. Proceedings of the Ocean Drilling Program, Initial Reports, vol. 104. College Station, TX (Ocean Drilling Program).CrossRefGoogle Scholar
Ellis, D., Bell, B. R., Jolley, D. W. & O'Callaghan, M. 2002. The stratigraphy, environment of eruption and age of the Faroes Lava Group, NE Atlantic Ocean. In The North Atlantic Igneous Province: Stratigraphy Tectonic, Volcanic and Magmatic Processes (eds Jolley, D. W. & Bell, B. R.), pp. 253–69. Geological Society of London, Special Publication no. 197.Google Scholar
Fliedner, M. M. & White, R. S. 2003. Depth imaging of basalt flows in the Faroe–Shetland Basin. Geophysical Journal International 152, 353–71.CrossRefGoogle Scholar
Greeley, R. 1982. The Snake River Plain, Idaho: representative of a new category of volcanism. Journal of Geophysical Research 87 (B4), 2705–12.CrossRefGoogle Scholar
Hald, N. & Waagstein, R. 1984. Lithology and chemstry of a 2-km sequence of Lower Tertiary tholeiitic lavas drilled on Suduroy, Faroe Islands (Lopra-1). In The Deep Drilling Project 1980–1981 in the Faroe Islands (eds Berthelsen, O., Noe-Nygaard, A. & Ramussen, J.), pp. 1518. Torshavn: Foroya Frodskaparfelag.Google Scholar
Hansen, D. M. 2006. The morphology of intrusion-related vent structures and their implications for constraining the timing of intrusive events along the NE Atlantic margin. Journal of the Geological Society, London 163, 789800.CrossRefGoogle Scholar
Hautot, S., Single, R. T., Watson, J., Harrop, N., Jerram, D. A., Tarits, P., Whaler, K. & Dawes, G. 2007. 3-D magnetotelluric inversion and model validation with gravity data for the investigation of flood basalts and associated volcanic rifted margins. Geophysical Journal International 170, 1418–30.CrossRefGoogle Scholar
Jegen-Kulcsar, M. & Hobbs, R. W. 2005. Outline of a Joint Inversion of Gravity, MT and Seismic Data. Annales Societatis Scientarium Faeroensis 43, 163–7.Google Scholar
Jerram, D. A., Mountney, N. & Mountney, H. 1999. Facies architecture of the Etjo Sandstone Fm. and its interaction with the Basal Etendeka flood basalts of NW Namibia: implications for offshore analogues. In The oil and gas habitats of the South Atlantic (eds Cameron, N., Bate, R. & Clure, V.), pp. 367–80. Geological Society of London, Special Publication no. 153.Google Scholar
Jerram, D. A., Mountney, N., Holzförster, F. & Mountney, H. 1999. Internal stratigraphic relationships in the Etendeka Group in the Huab Basin, NW Namibia: Understanding the onset of flood volcanism. Journal of Geodynamics 28, 393418.CrossRefGoogle Scholar
Jerram, D. A., Mountney, N., Howell, J., Long, D. & Stollhofen, H. 2000. Death of a Sand Sea: An active erg systematically buried by the Etendeka flood basalts of NW Namibia. Journal of the Geological Society, London 157, 513–16.CrossRefGoogle Scholar
Jerram, D. A. & Stollhofen, H. 2002. Lava/sediment interaction in desert settings; are all peperite-like textures the result of magma–water interaction? Journal of Volcanology and Geothermal Research 114, 231–49.CrossRefGoogle Scholar
Jerram, D. A. 2002. Volcanology and facies architecture of flood basalts. In Volcanic Rifted Margins (eds Menzies, M. A., Klemperer, S. L., Ebinger, C. J. & Baker, J.), pp. 121–35. Geological Society of America, Special Paper no. 362.Google Scholar
Jerram, D. A. & Widdowson, M. 2005. The anatomy of Continental Flood Basalt Provinces: geological constraints on the processes and products of flood volcanism. Lithos 79, 385405.CrossRefGoogle Scholar
Jolley, D. W. 2009. Palynofloral evidence for the onset and cessation of eruption of the Faroe Islands lava field. Faroe Islands Exploration Conference: Proceedings of the 2nd Conference. Annales Societatis Scientarium Faroensis, in press.Google Scholar
Jolley, D. W., Clarke, B. & Kelley, S. P. 2002. Paleogene time scale Miscalibration: Evidence from the dating of the North Atlantic igneous province. Geology 30, 710.2.0.CO;2>CrossRefGoogle Scholar
Jones, S. M., White, N. J., Clarke, B., Rowley, E. & Gallagher, K. 2002. Present and past influence of the Iceland plume on sedimentation, In Exhumation of the North Atlantic Margin: Timing, Mechanisms and Implications for Petroleum Exploration (eds Doré, A. G., Cartwright, J. A., Stoker, M. S., Turner, J. P. & White, N.), pp. 1325. Geological Society of London, Special Publication no. 196.Google Scholar
Kimbell, G. S., Ritchie, J. D., Johnson, H. & Gatliff, R. W. 2005. Controls on the structure and evolution of the NE Atlantic margin revealed by regional potential field imaging and 3D modelling. In Petroleum Geology: NW Europe and Global Perspectives: Proceedings of the 6th Conference (eds Doré, A. G. & Vining, B.), pp. 933–45. London: Geological Society.Google Scholar
Kjorboe, L. 1999. Stratigraphic relationships of the Lower Tertiary of the Faroe Basalt Plateau and the Faroe–Shetland Basin. In Petroleum Geology of NW Europe, Proceedings of the 5th Conference (eds Fleet, A. J. & Boldy, S. A. R.), pp. 559–72. London: Geological Society.Google Scholar
Laier, T., Jørgensen, O. & Isaksen, G. H. 1997. Hydrocarbon traces in the Tertiary basalts of the Faroe Islands. Marine and Petroleum Geology 14, 257–66.CrossRefGoogle Scholar
Maclennan, J. & Jones, S. M. 2006. Regional uplift, gas hydrate dissociation and the origins of the Paleocene–Eocene Thermal Maximum. Earth and Planetary Science Letters 245, 6580.CrossRefGoogle Scholar
Martini, F., Hobbs, R. W., Bean, C. J. & Single, R. T. 2005. A complex 3D volume for subbasalt imaging. First Break 23, 4151.CrossRefGoogle Scholar
Moore, J. G., Phillips, R. L., Grigg, R. W., Peterson, D. W. & Swanson, D. A. 1973. Flow of lava into the sea, 1969–71, Kilauea volcano, Hawaii. Geological Society of America Bulletin 84, 537–46.2.0.CO;2>CrossRefGoogle Scholar
Mountney, N., Howell, J., Flint, S. & Jerram, D. A. 1999. Climate, sediment supply and tectonics as controls on the deposition and preservation of the aeolian-fluvial Etjo Sandstone Formation, Namibia. Journal of the Geological Society, London 156, 771–7.CrossRefGoogle Scholar
Naylor, P. H., Bell, B. R., Jolley, D. W., Durnall, P. & Fredsted, R. 1999. Palaeogene magmatism in the Faroe–Shetland Basin: influences on uplift history and sedimentation. In Petroleum Geology of NW Europe, Proceedings of the 5th Conference (eds Fleet, A. J. & Boldy, S. A. R.), pp. 545–58. London: Geological Society.Google Scholar
Nelson, C. E., Jerram, D. A., Single, R. T. & Hobbs, R. W. 2009. Understanding the facies architecture of flood basalts and volcanic rifted margins and its effect on geophysical properties. Faroe Islands Exploration Conference: Proceedings of the 2nd Conference. Annales Societatis Scientarium Faroensis, in press.Google Scholar
Passey, S. R. & Bell, B. R. 2007. Morphologies and emplacement mechanisms of the lava flows of the Faroe Islands Basalt Group, Faroe Islands, NE Atlantic Ocean. Bulletin of Volcanology 70, 139–56.CrossRefGoogle Scholar
Pedersen, G. K., Larsen, L. M., Pedersen, A. K. & Hjortkjær, B. F. 1998. The syn-volcanic Naajaat lake, Paleocene of West Greenland. Palaeogeography, Palaeoclimatology, Palaeoecology 140, 271–87.CrossRefGoogle Scholar
Petry, K., Jerram, D. A, de Almeida, D. D. M. & Zerfass, H. 2007. Volcanic-sedimentary features in the Serra Geral Fm., Parana Basin, southern Brazil: Examples of dynamic lava-sediment interactions in an arid setting. Journal of Volcanology and Geothermal Research 159, 313–25.CrossRefGoogle Scholar
Planke, S., Alvestad, E. & Skogseid, J. 1999. Seismic characteristics of basaltic extrusive and intrusive rocks. The Leading Edge 18, 342–8.CrossRefGoogle Scholar
Planke, S., Symonds, P. A., Alvestad, E. & Skogseid, J. 2000. Seismic volcanostratigraphy of large-volume basaltic extrusive complexes on rifted margins. Journal of Geophysical Research 105, 19335–51.CrossRefGoogle Scholar
Planke, S., Rasmussen, T., Rey, S. S. & Myklebust, R. 2005. Seismic characteristics and distribution of volcanic intrusions and hydrothermal vent complexes in the Vøring and Møre basins. In Petroleum Geology: NW Europe and Global Perspectives: Proceedings of the 6th Conference (eds Doré, A. G. & Vining, B.), pp. 833–44. London: Geological Society.Google Scholar
Rasmussen, J. & Noe-Nygaard, A. 1970. Geology of the Faeroe Islands (Pre-Quaternary). Trans: Henderson, G., Geological Survey of Denmark, Copenhagen (1/25).CrossRefGoogle Scholar
Single, R. T. & Jerram, D. A. 2004. The 3-D facies architecture of flood basalt provinces and their internal heterogeneity: examples from the Palaeogene Skye Lava Field. Journal of the Geological Society, London 161, 911–26.CrossRefGoogle Scholar
Smallwood, J. R. & Maresh, J. 2002. The properties, morphology and distribution of igneous sills: modelling, borehole data and 3D seismic from the Faroe–Shetland area. In The North Atlantic Igneous Province: Stratigraphy, Tectonic, Volcanic and Magmatic Processes (eds Jolley, D. W. & Bell, B. R.), pp. 271306. Geological Society of London, Special Publication no. 197.Google Scholar
Spitzer, R., White, R. S. & iSIMM, Team. 2005. Advances in seismic imaging through basalts: a case study from the Faroe–Shetland Basin Alternate or journal title. Petroleum Geoscience 11, 147–56.CrossRefGoogle Scholar
Thomson, K. 2005. Volcanic features of the North Rockall Trough: application of visualisation techniques on 3D seismic reflection data. Bulletin of Volcanology 67, 116–28.CrossRefGoogle Scholar
Waagstein, R. 1988. Structure, composition and age of the Faroe basalt plateau. In Early Tertiary Volcanism and the Opening of the NE Atlantic (eds Morton, A. C. & Parson, L. M.), pp. 225–38. Geological Society of London, Special Publication no. 39.Google Scholar
Waagstein, R. 2006. Composite log from the Lopra-1/1A well, Faroe Islands. In Scientific results from the deepened Lopra-1 borehole, Faroe Islands (eds Chalmers, J. A. & Waagstein, R.). Geological Survey of Denmark and Greenland Bulletin, no. 9, inset.Google Scholar
Waagstein, R., Guise, P. & Rex, D. 2002. K/Ar and 39Ar/40Ar whole-rock dating of zeolite facies metamorphosed flood basalts: the upper Paleocene basalts of the Faroe Islands, NE Atlantic. In The North Atlantic Igneous Province: Stratigraphy Tectonic, Volcanic and Magmatic Processes (eds Jolley, D. W. & Bell, B. R.), pp. 219–52. Geological Society of London, Special Publication no. 197.Google Scholar
White, R. S., Smallwood, J. R., Fliedner, M. M., Boslaugh, B., Maresh, J. & Fruehn, J. 2003. Imaging and regional distribution of basalt flows in the Faroe–Shetland Basin. Geophysical Prosepecting 51, 215–31.CrossRefGoogle Scholar
Ziolkowski, A., Hanssen, P., Gatcliff, R., Jakubowicz, H., Dobson, A., Hampson, G., Li, X.-Y. & Liu, E. 2003. Use of low frequencies for sub-basalt imaging. Geophysical Prospecting 51, 169–82.CrossRefGoogle Scholar
Ziska, H. & Andersen, C. 2005. Exploration opportunities in the Faroe Islands. In Faroe Islands exploration conference: Proceedings of the 1st conference (eds Ziska, H., Warming, T. & Bloch, D.), pp. 146–62. Annales Societatis Scientiarum Færoensis Supplementum 43.Google Scholar
Supplementary material: Image

Jerram supplementary colour figure

Jerram supplementary colour figure

Download Jerram supplementary colour figure(Image)
Image 1.4 MB