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The geochemical stratigraphy, field relations and temporal variation of the Mull–Morvern Tertiary lava succession, NW Scotland

Published online by Cambridge University Press:  03 November 2011

Andrew Craig Kerr
Affiliation:
Department of Geological Sciences, University of Durham, South Rd, Durham, DH1 3LE, UK

Abstract

The early Tertiary Mull-Morvern lava succession, NW Scotland, represents the thickest continuous section (1000 m from sea level to the top of Ben More) of Tertiary lavas exposed in the UK. This succession has been sampled and geochemically analysed, on a flow-by-flow basis, throughout the lava succession. Field observations during the course of this sampling suggest that the early lava flows (the Staffa Magma sub-Type) ponded in palaeovalleys along with interlava sediments. In the main part of the Mull lava succession (the Mull Plateau Group) the lava flows are on average ∼ 5 m thick. Most previous Hebridean workers have assumed that the red horizons commonly found between these later lava flows, represent weathered flow tops. However, this study has shown that in some places these red ‘boles’ appear to be a combination of both volcanic ash and weathered basalt.

Chemically distinctive units of flows have been found throughout the succession. The two most abundant magma sub-types of the Mull Plateau Group, primitive (>9wt% MgO) basalts with Ba/Nb» 15 and more evolved (<9wt% MgO) basalts-hawaiites with Ba/Nb<15, form packets of flow units which can be up to 200 m thick. These chemically distinctive flow units have been correlated across the lava succession. However, the correlation of individual lava flows has proved difficult. The Mull Plateau Group lavas generally become more evolved and less contaminated with continental crust towards the top of the succession, culminating in the trachytes of the Pale Group on Ben More. Basaltic lavas above the Pale Group have markedly different trace element ratios, and seem to represent shallower, more extensive asthenospheric melting than the Mull Plateau Group.

Type
Research Article
Copyright
Copyright © Royal Society of Edinburgh 1995

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References

Allwright, E. A. 1980. The structure and petrology of the volcanic rocks of Eigg, Muck and Canna, N.W. Scotland. Unpublished MSc Thesis, University of Durham, UK.Google Scholar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 G.BR, SCOTLAND.Google Scholar
Bell, B. R. & Harris, J. W. 1986. An excursion guide to the Geology of Skye. Glasgow: Geological Society of Glasgow, 317pp.Google Scholar
Bott, M. H. P. 1988. A new look at the causes and consequences of the Icelandic hot-spot. In: Early Tertiary Volcanism and the Opening of the NE Atlantic. Morton, A. C. and Parson, L. M. eds. GEOL SOC SPEC LONDON PUBL 39, 1523.CrossRefGoogle Scholar
Cas, R. A. F. & Wright, J. V. 1987. Volcanic Successions. London: Unwin Hyman.CrossRefGoogle Scholar
Emeleus, C. H. 1985. The Tertiary lavas and sediments of north-west Rhum, Inner Hebrides. GEOL MAG 122, 419–37.CrossRefGoogle Scholar
Emeleus, C. H. 1991. Tertiary igneous activity. In Craig, G. Y. (ed.) Geology of Scotland, 455502, London: Geological Society of London.Google Scholar
Fawcett, J. J. 1961. The petrology of the flood basalts of the Isle of Mull, Argyllshire. Unpublished PhD Thesis, University of Manchester, UK.Google Scholar
Gardiner, J. S. 1887. On the leaf beds and gravels of Ardtun, Carsaig etc. in Mull. Q J GEOL SOC LOND 43, 270300.CrossRefGoogle Scholar
Harker, A. 1904. The Tertiary igneous rocks of Skye. MEM GEOL SURV GR BR, SCOTLAND.CrossRefGoogle Scholar
Kent, R. W. 1995. Magnesian basalts from the Hebrides, Scotland: chemical composition and relationship to the Icelandic mantle plume. J GEOL SOC LONDON, 152, in press.CrossRefGoogle Scholar
Kerr, A. C. 1993a. Elemental evidence for an enriched small-fraction melt input into Tertiary Mull basalts, Western Scotland. J GEOL SOC LONDON, 150, 763–69.CrossRefGoogle Scholar
Kerr, A. C. 1993b. The geochemistry and petrogenesis of the Mull and Morvern Tertiary lava succession, Argyll, Scotland. Unpublished PhD Thesis University of Durham, UK.Google Scholar
Kerr, A. C. 1994. Lithospheric thinning during the evolution of continental Large Igneous Provinces: A case study from the North Atlantic Tertiary province. GEOLOGY 22, 1027–30.2.3.CO;2>CrossRefGoogle Scholar
Kerr, A. C. 1995. The geochemistry of the Mull-Morvern Tertiary lava succession, NW Scotland; an assessment of mantle sources during plume related volcanism. CHEM GEOL, 122, 4358.CrossRefGoogle Scholar
Kerr, A. C.Kempton, P. D. & Thompson, R. N. 1995. Crustal assimilation during turbulent magma ascent (ATA); New isotopic evidence from the Mull Tertiary lava succession, N.W. Scotland. CONTRIB MINER PETROL, 119, 142–54.CrossRefGoogle Scholar
Larsen, L. M., Watt, W. S. & Watt, M. 1989. Geology and petrology of the lower Tertiary plateau basalts of the Scoresby Sund region, East Greenland. BULL GREENLAND GEOL SUR 157, 162p.Google Scholar
Morrison, M. A., Thompson, R. N., Gibson, I. L. & Marriner, G. F. 1980. Lateral chemical heterogeneity in the Palaeocene upper mantle beneath the Scottish Hebrides. PHILOS TRANS R SOC LONDON A297, 229–44.Google Scholar
Preston, J. 1982. Eruptive volcanism. In Sutherland, D. (ed.) Igneous rocks of the British Isles. Chichester: Wiley.Google Scholar
Schilling, J. G. 1973. Iceland mantle plume: geochemical evidence along Reykjanes Ridge. NATURE 242, 565–71.CrossRefGoogle Scholar
Skelhorn, R. R. 1969. The Tertiary igneous geology of the Isle of Mull. GEOL ASSOC GUIDES, 20.Google Scholar
Sun, S.-S. & McDonough, W. F. 1989. Chemical and isotopic systematics of oceanic basalts: implications for mantle compositions and processes. In Saunders, A. D. & Norry, M. J. (eds) Magmatism in the Ocean Basins. GEOL SOC SPEC PUBL 42, 313–45.CrossRefGoogle Scholar
Thompson, R. N. 1982. Magmatism of the British Tertiary Province. SCOTTISH J GEOL 18, 49107.CrossRefGoogle Scholar
Thompson, R. N., Morrison, M. A.Dickin, A. P., Gibson, I. L. & Harmon, R. S. 1986. Two contrasted styles of interaction between basic magmas and continental crust in the British Tertiary Volcanic Province. J GEOPHY RES 91, 5985–97.CrossRefGoogle Scholar
Walker, G. P. L. 1970. The distribution of amygdale minerals in Mull and Morvern Western Scotland. In Murty, T. V. V. G. R. K. and Rao, S. S. (eds) Studies in Earth Sciences, West Commemoration Volume 181–94.Google Scholar
White, R. S. 1988. A hot-spot model for early Tertiary volcanism in the North Atlantic. In Morton, A. C. & Parson, L. M. (eds) Early Tertiary Volcanism and the Opening of the NE Atlantic. GEOL SOC SPEC PUBL 39, 313.CrossRefGoogle Scholar
Williamson, I. T. & Bell, B. 1994. The Palaeocene lava field of West-Central Skye, Scotland: Stratigraphy, palaeogeography and structure. TRANS R SOC EDINBURGH: EARTH SCI 85, 3975.CrossRefGoogle Scholar