Hostname: page-component-cd9895bd7-7cvxr Total loading time: 0 Render date: 2024-12-23T15:02:23.861Z Has data issue: false hasContentIssue false

The Palaeocene lava field of west-central Skye, Scotland: Stratigraphy, palaeogeography and structure

Published online by Cambridge University Press:  03 November 2011

I. T. Williamson
Affiliation:
British Geological Survey, Kingsley Dunham Centre, Keyworth, Nottinghamshire NG12 5GG, England
B. R. Bell*
Affiliation:
Department of Geology & Applied Geology, University of Glasgow, Glasgow G12 8QQ, Scotland
*
*To whom all correspondence should be addressed

Abstract

Palaeocene volcanic activity is represented in west-central Skye, Inner Hebrides, Scotland, by a laterally extensive and thick pile of sub-aerial lavas mainly belonging to the alkali olivine basalt—hawaiite—mugearite—benmoreite—trachyte suite. The lavas are typical of many continental flood basalt suites and were principally fed from fissure eruptions similar to those of present day Iceland. Intercalated with the lavas are rare beds of heterogeneous volcaniclastic material, including breccias, conglomerates, sandstones and mudstones. The sequence forms a major portion of a larger volcanic field preserved within the NNE-SSW-elongated ‘Sea of the Hebrides’ sedimentary basin.

Significant hiatuses in the volcanic activity are marked by deep-weathering profiles and thin sedimentary sequences comprising mudstones, ironstones, coals, sandstones and conglomerates. Palaeocurrent indicators and clast lithologies within the clastic sedimentary rocks indicate that erosion of a massif dominated by the Palaeocene Rum Igneous Complex and its roof rocks, c. 20 km to the S, provided abundant detritus to a river system which drained towards the N. Such sedimentary intercalations aid the stratigraphical subdivision of the lava field. Eight lava groups, each most likely with a different focus of fissure eruption, and divisible into mappable formations, together with two sedimentary formations, are recognised.

The alkali olivine basalts are typically thin, with a tendency to form compound flows with limited lateral extents, whilst the hawaiites and mugearites are considerably thicker and cover large areas. Only very rarely are flow terminations observed. The original extents of the single benmoreite and rare trachytes cannot be determined from their limited erosional remnants. The more evolved flows tended to occur after brief hiatuses in the volcanic activity, indicated by well-developed lateritic tops to the underlying flows.

The youngest preserved lava is a columnar-jointed olivine tholeiite with a MORB-like composition. The flow is at least 120 m thick and apparently ponded in a steep-sided palaeo-valley within the lava field.

Three fault trends are recognised: parallel, normal and marginally oblique to the main NW-SEtrending regional dyke swarm, and dissect the lava field into a number of discrete blocks. The more significant of these faults may have been active during the development of the lava field, and in some instances instrumental in controlling the distribution of the flows.

Later Tertiary erosion has removed an unknown thickness of material from the upper part of the lava field, the preserved thickness of which is estimated to be about 1·5 km.

Type
Research Article
Copyright
Copyright © Royal Society of Edinburgh 1994

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.)

References

Allwright, E. A. 1980. The structure and petrology of the Tertiary volcanic rocks of Eigg, Muck and Canna N. W. Scotland. Unpublished MSc thesis, University of Durham.Google Scholar
Anderson, F. W. & Dunham, K. C. 1966. The Geology of Northern Skye. MEM GEOL SURV GREAT BRITAIN.Google Scholar
Bailey, E. B., Clough, C. T., Wright, W. B., Richey, J. E. & Wilson, G. V. 1924. Tertiary and Post-Tertiary Geology of Mull, Loch Aline, and Oban. MEM GEOL SURV GREAT BRITAIN.Google Scholar
Barrow, G, Clough, C. T., Harker, A., Wedd, C. B. and Woodward, H. B. 1909. Glenelg: 1 inch to 1 mile geological map. GEOL SURV GREAT BRITAIN.Google Scholar
Bell, B. R. & Harris, J. W. 1986. An Excursion Guide to the Geology of the Isle of Skye. Glasgow: Geological Society of Glasgow.Google Scholar
Bell, B. R. & Williamson, I. T. 1994. Picritic basalts from the Palaeocene lava field of west-central Skye, Scotland: evidence for parental magma compositions. MINER MAG (in press).CrossRefGoogle Scholar
Binns, P. E., McQuillin, R. & Kenolty, N. 1973. The Geology of the Sea of the Hebrides. Report of the Institute of Geological Sciences, 73/14.Google Scholar
Boue, A. 1820. Short comparison of the volcanic rocks of France with those of a similar nature found in Scotland. EDINBURGH PHILOS J 2, 326.Google Scholar
Cas, R. A. F. & Wright, J. V. 1987. Volcanic Successions: Modern and Ancient. London: Allen & Unwin.CrossRefGoogle Scholar
Clough, C. T. & Harker, A. 1904a. Minginish: 1 inch to 1 mile geological map. GEOL SURV GREAT BRITAIN.Google Scholar
Clough, C. T. & Harker, A. 1904b. The Geology of west-central Skye, with Soay. MEM GEOL SURV SCOTLAND.Google Scholar
Cole, R. B. & Ridgway, K. D. 1993. The influence of volcanism on fluvial deposition systems in a Cenozoic strike-slip basin, Denali Fault System, Yukon Territory, Canada. J SED PETROL 63, 152–66.Google Scholar
Dagley, P. & Mussett, A. E. 1981. Palaeomagnetism of the British Tertiary igneous province: Rum and Canna. GEOPHYS J R ASTR SOC 65, 475–91.CrossRefGoogle Scholar
Dagley, P., Mussett, A. E. & Skelhorn, R. R. 1990. Magnetic polarity of the Tertiary igneous rocks of Skye, Scotland. GEOPHYS J INT 101, 395409.CrossRefGoogle Scholar
Davies, D. K., Vessel, R. K., Miles, R. C, Foley, M. G. & Bonis, S. B. 1978. Fluvial transport and downstream sediment modification in an active volcanic region. In Miall, A. D. (ed.) Fluvial Sedimentology, 6184. CAN SOC PETROL GEOL MEM 5.Google Scholar
Emeleus, C. H. 1973. Granophyre pebbles in Tertiary conglomerates on the Isle of Canna, Inverness-shire. SCOTT J GEOL 9, 157–9.CrossRefGoogle Scholar
Emeleus, C. H. 1985. The Tertiary lavas and sediments of northwest Rum, Inner Hebrides. GEOL MAG 122, 419–37.Google Scholar
Emeleus, C. H. 1991. Tertiary Igneous Activity. In Craig, G. Y. (ed.) The Geology of Scotland, (3rd edn). 455502. Edinburgh: Scottish Academic Press (3rd edition).Google Scholar
Emeleus, C. H. & Forster, R. M. 1979. Field Guide to the Tertiary Igneous Rocks of Rum. London: Nature Conservancy Council.Google Scholar
Emeleus, C. H. & Gyopari, M. C. 1992. British Tertiary Volcanic Province. London: Chapman & Hall.Google Scholar
England, R. W. 1992. The role of Palaeocene magmatism in the tectonic evolution of the Sea of the Hebrides Basin: implications for basin evolution on the NW Seaboard. In Parnell, J. (ed.) Basins on the Atlantic Seaboard: Petroleum Geology, Sedimentology and Basin Evolution, 163–74. London: Geological Society Special Publication No. 62.Google Scholar
England, R. W. 1994. The structure of the Skye Lava Field. SCOTT J GEOL 30, 3337.Google Scholar
Esson, J., Dunham, A. C. & Thompson, R. N. 1975. Low alkali, high calcium olivine tholeiite lavas from the Isle of Skye, Scotland. J PETROL 16, 488–97.Google Scholar
Fisher, R. V. & Smith, G. A. 1991. Sedimentation in volcanic settings. Society of Economic Paleontologists and Mineralogists. Special Publication 45.Google Scholar
Folk, R. L. 1974. Petrology of Sedimentary Rocks. Austin, Texas: Hemphill.Google Scholar
Geikie, A. 1871. On the Tertiary volcanic rocks of the British Islands. First Paper. QUART J GEOL SOC LONDON 27, 279311.CrossRefGoogle Scholar
Geikie, A. 1888. The history of volcanic action during the Tertiary period in the British Isles. TRANS R SOC EDINBURGH 35, 21184.CrossRefGoogle Scholar
Geikie, A. 1897. The Ancient Volcanoes of Great Britain. London: MacMillan & Co.CrossRefGoogle Scholar
Harker, A. 1904. The Tertiary igneous rocks of Skye. MEM GEOL SURV SCOTLAND.Google Scholar
Harker, A. 1908. The geology of the Small Isles of Inverness-shire (Rum, Canna, Eigg, Muck, etc.). MEM GEOL SURV SCOTLAND.Google Scholar
Judd, J. W. 1874. The Secondary rocks of Scotland. Second paper. On the ancient volcanoes of the Highlands and the relations of their products to the Mesozoic strata. Q J GEOL SOC LONDON 30, 220301.Google Scholar
Judd, J. W. 1889. The Tertiary volcanoes of the Western Isles of Scotland. Q J GEOL SOC LONDON 45, 187219.Google Scholar
MacCulloch, J. 1819. A Description of the Western Islands of Scotland, Including the Isle of Man: Comprising an Account of Their Geological Structure; with Remarks on their Agriculture, Scenery, and Antiquities. 3 volumes. (Skye, Vol. 1, 262419). London: Hurst Robinson.Google Scholar
Macdonald, G. A. 1960. Dissimilarity of continental and oceanic rock types. J PETROL 1, 172–7.Google Scholar
Meighan, I. G., Hutchison, R., Williamson, I. T. & Maclntyre, R. M. 1981. Geological evidence for the different relative ages of the Rum and Skye Tertiary central complexes. J GEOL SOC LONDON 139, 659.Google Scholar
Miall, A. D. 1970. Devonian alluvial fans, Prince of Wales Islands, Arctic Canada. J SED PETROL 40, 556–71.Google Scholar
Miall, A. D. 1977. A review of the braided stream depositional environment. EARTH SCI REV 13, 162.Google Scholar
Miall, A. D. 1978. Lithofacies types and vertical profile models in braided river deposits: A summary. In Miall, A. D. (ed.) Fluvial Sedimentology. CAN SOC PETROL GEOL MEM 5, 597604.Google Scholar
Miall, A. D. 1992. Alluvial deposits. In Walker, R. G. & James, N. P. (eds) Facies Models: Response to Sealevel Change, 119–42. Geological Association of Canada.Google Scholar
Middleton, L. T. & Trujillo, A. P. 1984. Sedimentology and depositional setting of the Upper Proterozoic Scanlan Conglomerate, central Arizona. In Koster, E. H. & Steel, R. J. (eds) Sedimentology of Gravels and Conglomerates, 189201. CAN SOC PETROL GEOL Mem 10.Google Scholar
Morton, N. 1987. Jurassic subsidence history in the Hebrides, NW Scotland. MARINE PETROL GEOL 4, 226–42.Google Scholar
Morton, N. 1989. Jurassic sequence stratigraphy in the Hebrides Basin, NW Scotland. MARINE PETROL GEOL 6, 243–60.Google Scholar
Muir, I. D. & Tilley, C. E. 1961. Mugearites and their place in the alkali igneous rock series. J GEOL 69, 186203.CrossRefGoogle Scholar
Mussett, A. E. 1984. Time and duration of Tertiary igneous activity of Rum and adjacent areas. SCOTT J GEOL 20, 273–79.CrossRefGoogle Scholar
Mussett, A. E., Dagley, P. & Skelhorn, R. R. 1988. Time and duration of activity in the British Tertiary Igneous Province. In Morton, A. C. & Parson, L. M. (eds) Early Tertiary Volcanism and the Opening of the NE Atlantic, 337–48. London: Geological Society Special Publication No. 39.Google Scholar
Peach, B. N., Horne, J., Woodward, H. B., Clough, C. T., Harker, A. & Wedd, C. B. 1910. The Geology of Glenelg, Lochalsh and south-east part of Skye. MEM GEOL SURV SCOTLAND.Google Scholar
Rust, B. R. 1978. Depositional models for braided alluvium. In Miall, A. D. (ed.) Fluvial Sedimentology, 605–25. CAN SOC PETROL GEOL MEM 5.Google Scholar
Rust, B. R. & Koster, E. H. 1984. Coarse alluvial deposits. In Walker, R. G. (ed.) Fades Models, 5369. 2nd edition.Google Scholar
Speight, J. M., Skelhorn, R. R., Sloan, T. & Knapp, R. J. 1982. The dyke swarms of Scotland. In Sutherland, D. S. (ed.) Igneous Rocks of the British Isles, 449–59. Chichester: John Wiley.Google Scholar
Thompson, R. N., Esson, J. & Dunham, A. C. 1972. Major element chemical variation in the Eocene lavas of the Isle of Skye, Scotland. J PETROL 13, 219–53.Google Scholar
Thornton, C. P. & Tuttle, O. F. 1960. Chemistry of igneous rocks. I. Differentiation Index. AMER J SCI 258, 664–84.CrossRefGoogle Scholar
Tilley, C. E. & Muir, I. D. 1964. Intermediate members of the oceanic basalt-trachyte association. GEOL FOR STOCKH FORH 85, 436–44.CrossRefGoogle Scholar
Vondra, C. F. & Burggraf, D. R. 1978. Fluvial facies of the Plio-Pleistocene Koobi Fora Formation, Karari Ridge, East Lake Turkana, Kenya. In Miall, A. D. (ed.) Fluvial Sedimentology, 511–29. CAN SOC PETROL GEOL Mem 5.Google Scholar
von Oeynhausen, C. & von Dechen, H. 1829. Die Insel Skye. KARSTEN'S ARCHIV FUR MIN etc. 1, 56104.Google Scholar
Williamson, I. T. 1979. The petrology and structure of the Tertiary volcanic rocks of west-central Skye, N.W. Scotland. Unpublished PhD thesis, University of Durham.Google Scholar
Wilson, R. L., Dagley, P. & Ade-Hall, J. M. 1972. Palaeomagnetism of the British Tertiary igneous province: Skye lavas. GEOPHYS J R ASTR SOC 28, 285–93.Google Scholar