Hostname: page-component-76fb5796d-2lccl Total loading time: 0 Render date: 2024-04-26T08:09:02.329Z Has data issue: false hasContentIssue false
  • English
  • Français

Meta-igneous granulite and ultramafic xenoliths from basalts of the Midland Valley of Scotland: petrology and mineralogy of the lower crust and upper mantle

Published online by Cambridge University Press:  03 November 2011

Robert H. Hunter ,
Brian G. J. Upton  and
Peder Aspen
Robert H. Hunter
Affiliation:
Grant Institute of Geology, University of Edinburgh, West Mains Road, Edinburgh, EH9 3JW, Scotland.
Brian G. J. Upton
Affiliation:
Grant Institute of Geology, University of Edinburgh, West Mains Road, Edinburgh, EH9 3JW, Scotland.
Peder Aspen
Affiliation:
Grant Institute of Geology, University of Edinburgh, West Mains Road, Edinburgh, EH9 3JW, Scotland.
Get access Rights & Permissions [Opens in a new window]

Abstract

Ultramafic xenolith lithologies representative of the mantle beneath the Midland Valley of Scotland comprise magnesian peridotite (predominantly spinel lherzolite) and cumulate wehrlites and clinopyroxenites. The lherzolites are typical of the worldwide type I (Cr-diopside) xenolith suite; their textures and mineral chemistry record a complex thermal and deformational history. The petrographical and mineralogical features of the wehrlite-clinopyroxenite suite can be interpreted within the context of a sequence of cpx + ol ± sp cumulates that have undergone a protracted period of subsoli dus re-equilibration. Mineral compositions are similar to those of type II (Al-augite) ultramafic xenolith suites.

Although xenolith populations imply widespread lower crustal heterogeneity, meta-igneous basic granulites form a major component of this region beneath the Midland Valley. They are principally composed of pi + cpx + mt ± opx ± ap; a modal continuum exists from clinopyroxenite to anorthosite, skewed towards plagioclase-rich lithologies. Garnet is rare. Locally, evidence indicates re-equilibration from garnet granulite precursors. Rock densities range from c. 2·8 to c. 3·2 gm . cm−3, implying P-wave velocities in the range 6·5–7·5 km . s−1 consistent with the known seismic properties of the lower crustal layer beneath the Midland Valley. Phase relations are also consistent with equilibration of primary assemblages at depths of 20–35 km. Retrograde reactions indicate that portions of the crust may have had a complex pressure-temperature-time evolution. Major element compositions of the granulites are broadly basaltic, ranging from ne to hy normative with the mean corresponding to alkali olivine basalt. They are distinct, chemically, from basic granulites of the Lewisian complex of NW Scotland.

Keywords

clinopyroxenitelherzolitelithospheremetagabbrometamorphicwehrlite
Type
Regional framework
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 75 , Issue 2: Deep Geology of the Midland Valley of Scotland and Adjacent Regions. Bicentenary Symposium , 1984 , pp. 75 - 84
Copyright
Copyright © Royal Society of Edinburgh 1984

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

Arculus, R. J. 1975. Melting behaviour of two basanites in the range 10–35 kbar and the effect of TiO2 on the olivine-diopside reaction at high pressures. CARNEGIE INST WASHINGTON YEARB 74, 512–5.Google Scholar
Bamford, D., Nunn, K., Prodehl, C. & Jacob, B. 1977. LISPB-III. Upper crustal structure of northern Britain. J GEOL SOC LONDON 133, 481–8.Google Scholar
Basaltic Volcanism Study Project 1981. Basaltic volcanism on the terrestrial planets. New York: Pergamon.Google Scholar
Bohlen, S. R., Wall, V. J. & Boettcher, A. L. 1983. Experimental investigation and application of garnet granulite equilibria. CONTRIB MINERAL PETROL 83, 5261.Google Scholar
Brewer, J. A., Matthews, D. H., Warner, M. R., Hall, J., Smythe, D. K. & Whittington, R. J. 1983. BIRPS deep seismic reflection studies of the British Caledonides. NATURE 305, 206–10.CrossRefGoogle Scholar
Brown, G. M., Pinsent, R. H. & Coisy, P. 1980. The petrology of spinel peridotite xenoliths from the Massif Central, France. AM J SCI 280A, 471–98.Google Scholar
Chapman, N. A. 1975. An experimental study of spinel clinopyroxenite xenoliths fromthe Duncansby Ness Vent, Caithness, Scotland. CONTRIB MINERAL PETROL 51, 223–30.Google Scholar
Chapman, N. A. 1976. Inclusions and megacrysts from undersaturated tuffs and basanites, E. Fife, Scotland. J PETROL 17, 472–98.Google Scholar
Christensen, N. & Fountain, D. 1975. Constitution of the lower crust based on experimental studies of seismic velocities in granulite. BULL GEOL SOC AM 86, 227–36.Google Scholar
Donaldson, C. H. 1978. Petrology of the uppermost upper mantle deduced from spinel lherzolite and harzburgite nodules from Carlton Hill, Derbyshire. CONTRIB MINERAL PETROL 65, 363–77.CrossRefGoogle Scholar
Dostal, J., Dupuy, C. & Leyreloup, A. 1980. Geochemistry and petrology of metaigneous granulitic xenoliths in Neogene volcanic rocks from the Massif Central, France—implications for the lower crust. EARTH PLANET SCI LETT 50, 3140.Google Scholar
Frey, F. A. & Prinz, M. 1978. Ultramafic inclusions from San Carlos, Arizona: Petrologic and geochemical data bearing on their petrogenesis. EARTH PLANET SCI LETT 38, 129–76.Google Scholar
Goldsmith, J. R. 1975. Scapolites, granulites, and volatiles in the lower crust. BULL GEOL SOC AM 87, 161–8.Google Scholar
Graham, A. M. & Upton, B. G. J. 1978. Gneisses in diatremes, Scottish Midland Valley: Petrology and tectonic implications. J GEOL SOC LONDON 135, 219–28.CrossRefGoogle Scholar
Griffin, W. L., Carswell, D. A. & Nixon, P. H. 1979. Lower crustal granulites and eclogites from Lesotho, Southern Africa. In Boyd, F. R. & Meyer, H. O. A. (eds) The mantle sample: Inclusions in kimberlites and other volcantes, 5984. Washington: American Geophysical Union.Google Scholar
Griffin, W. L., Wass, S. Y. & Hollis, J. D. 1984. Ultramafic xenoliths from Bullenmerri and Gnotuk maars, Victoria, Australia: petrology of a subcontinental crust-mantle transition. J PETROL 25, 5387.Google Scholar
Hall, J., Brewer, J. A., Matthews, D. H. & Warner, M. R. 1984. Crustal structure across the Caledonides from the ‘WINCH’ seismic reflection profile: influences on the evolution of the Midland Valley of Scotland. TRANS R SOC EDINBURGH EARTH SCI 75, 97109.CrossRefGoogle Scholar
Halliday, A. N. 1984. Coupled Sm–Nd and U–Pb systematics in late-Caledonian granites and the basement under northern Britain. NATURE 307, 229–33.CrossRefGoogle Scholar
Halliday, A. N., Aftalion, M., van Breemen, O. & Jocelyn, J. 1979. Petrographic significance of Rb–Sr and U–Pb isotopic systems in the 400 ma old British Isles granitiods and their hosts. In Harris, A. L., Holland, C. H. & Leake, B. E. (eds) The Caledonides of the British Isles—reviewed, 653–61. SPEC PUBL GEOL SOC LONDON 8.Google Scholar
Halliday, A. N., Aftalion, M., Upton, B. G. J., Aspen, P. & Jocelyn, J. 1984. U–Pb isotopie ages from a granulite-facies xenolith from Partan Craig in the Midland Valley of Scotland. TRANS R SOC EDINBURGH EARTH SCI 75, 7174.Google Scholar
Harris, A. L., Holland, C. H. & Leake, B. E. 1979. The Caledonides of the British Isles—reviewed. SPEC PUBL GEOL SOC LONDON 8.Google Scholar
Holland, J. G. & Lambert, R. St J. 1973. Comparative major element geochemistry of the Lewisian of the mainland of Scotland. In Park, R. G. & Tarney, J. (eds) The Early Precambrian of Scotland and Related Rocks of Greenland, 5162. University of Keele.Google Scholar
Irving, A. J. 1974. Geochemical and high-pressure experimental studies of garnet pyroxenite and pyroxene granulite xenoliths from the Delegate basaltic pipes, Australia. J PETROL 15, 140.Google Scholar
Irving, A. J. 1980. Petrology and geochemistry of composite ultramafic xenoliths in alkalic basalts and implications for magmatic processes within the mantle. AM J SCI 280A, 389426.Google Scholar
Kay, R. W. & Kay, S. M. 1981. The nature of the lower continental crust: inferences from geophysics, surface geology and crustal xenoliths. REV GEOPHYS SPACE PHYS 19, 271–97.Google Scholar
Leggett, J., McKerrow, W. S. & Soper, N. J. 1983. A model for the crustal evolution of southern Scotland. TECTONICS 2, 187210.Google Scholar
Leyreloup, A., Bodinier, J. L., Dupuy, C. & Dostal, J. 1982. Petrology and geochemistry of granulite xenoliths from central Hoggar (Algeria)—implications for the lower crust. CONTRIB MINERAL PETROL 79, 6875.Google Scholar
Lindsley, D. H. 1983. Pyroxene thermometry. AM MINERAL 68, 477–93.Google Scholar
Menzies, M. 1983. Mantle ultramafic xenoliths in alkaline magmas: Evidence for mantle heterogeneity modified by magmatic activity. In Hawkesworth, C. J. & Norry, M. J. (eds) Continental basalts and mantle xenoliths, 92110. Nantwich: Shiva.Google Scholar
O'Hara, M. J. 1961. Zoned ultramafic and basic gneiss masses in the early lewisian metamorphic complex at Scourie, Sutherland. J PETROL 2, 248–76.Google Scholar
Pidgeon, R. J. & Aftalion, M. 1978. Cogenetic and inherited zircon U–Pb systems in granites of Scotland and England. In Bowes, D. R. & Leake, B. E. (eds) Crustal evolution in northwestern Britain and adjacent regions, 183248. GEOL J SPEC ISSUE 10.Google Scholar
Pollack, H. N. & Chapman, D. S. 1977. On the regional variation of heat-flow, geotherms and lithospheric thickness. TECTO-NOPHYSICS 38, 279–96.Google Scholar
Praegel, N.-O. 1981. Origin of ultramafic inclusions and megacrysts in a monchiquite dyke at Streap, Inverness-shire, Scotland. LITHOS 14, 305–22.Google Scholar
Savage, D. & Sills, J. D. 1980. High pressure metamorphism in the Scourian of NW Scotland: evidence from garnet granulites. CONTRIB MINERAL PETROL 74, 153–63.Google Scholar
Sheraton, J. W., Skinner, A. C. & Tarney, J. 1973. The geochemistry of the Scourian gneisses of the Assynt district. In Park, R. G. & Tarney, J (eds) The Early Precambrian of Scotland and Related Rocks of Greenland, 1330. University of Keele.Google Scholar
Sutherland, F. L. & Hollis, J. D. 1982. Mantle-lower crustal petrology from inclusions in basaltic rocks in eastern Australia—an outline. J VOLCANOL GEOTHERM RES 14, 129.Google Scholar
Sweatman, T. R. & Long, J. V. P. 1969. Quantitative electron probe analysis of rock-forming minerals. J PETROL 10, 332–79.Google Scholar
Thompson, R. N. 1972. Melting behaviour of two Snake River lavas at pressures up to 35 kbar. CARNEGIE INST WASHINGTON YEARB 71, 406–10.Google Scholar
Upton, B. G. J., Aspen, P. & Chapman, N. A. 1983. The upper mantle and deep crust beneath the British Isles: Evidence from inclusion suites in volcanic rocks. J GEOL SOC LONDON 140, 105–22.Google Scholar
Upton, B. G. J., Aspen, P. & Hunter, R. H. 1984. Xenoliths and their implications for the deep geology of the Midland Valley of Scotland and adjacent regions. TRANS R SOC EDINBURGH EARTH SCI 75, 6570.Google Scholar
Wass, S. Y. & Hollis, J. D. 1983. Crustal growth in southeastern Australia—Evidence from lower crustal eclogitic and granulitic xenoliths. J METAMORPH GEOL 1, 2545.Google Scholar
Weaver, B. L. & Tarney, J. 1980. Rare-earth geochemistry of Lewisian granulite facies gneisses, northwestern Scotland: Implications for the petrogenesis of the Archaean lower crust. EARTH PLANET SCI LETT 51, 279–96.Google Scholar
Wells, P. R. A. 1977. Pyroxene thermometry in simple and complex systems. CONTRIB MINERAL PETROL 62, 129–39.CrossRefGoogle Scholar
Wilkinson, J. F. G. 1975. An Al-spinel ultramafic-mafic inclusion suite and high-pressure megacrysts in an analcimite and their bearing on basaltic magma fractionation at elevated pressures. CONTRIB MINERAL PETROL 53, 71104.Google Scholar
Wilshire, H. G. & Shervais, J. W. 1975. Al-augite and Cr-diopside ultramafic xenoliths in basaltic rocks from the western United States. PHYS CHEM EARTH 9, 257–72.Google Scholar