Hostname: page-component-76fb5796d-45l2p Total loading time: 0 Render date: 2024-04-29T20:17:05.470Z Has data issue: false hasContentIssue false
  • English
  • Français

A SHRIMP ion microprobe study of inherited and magmatic zircons from four Scottish Caledonian granites

Published online by Cambridge University Press:  03 November 2011

R. T. Pidgeon  and
W. Compston
R. T. Pidgeon
Affiliation:
R. T. Pidgeon, School of Applied Geology, Curtin University of Technology, GPO Box U 1987, Perth WA6001, Australia
W. Compston
Affiliation:
W. Compston, Research School of Earth Sciences, The Australian National University, GPO Box 4, Canberra City, ACT 2601, Australia
Get access Rights & Permissions [Opens in a new window]

Abstract

Using the ion microprobe SHRIMP we have analysed zircons from the Ben Vuirich, Glen Kyllachy, Inchbae and Vagastie Bridge granites from the Scottish Caledonides, in an attempt to resolve the ages of inherited zircons shown to be present in these granites by previous conventional multigrain analyses. Middle Proterozoic age components were found in inherited zircons from all four granites. Late Proterozoic (900–1,100 Ma) components have been identified in zircons from the Glen Kyllachy and Ben Vuirich granites in the Grampian Highlands. A Late Archaean age has only been detected in one zircon from the Glen Kyllachy granite. The distribution of inherited components in the granite zircon populations could reflect fundamental divisions in the age composition of granite source rocks; however, detailed assessment of this possibility must await further ion microprobe analyses on zircons from many more granites.

SHRIMP isotopic and U, Th and Pb analyses were made on successive shells of zoned zircon surrounding inherited cores from the Glen Kyllachy granite to monitor chemical changes during magmatic zircon growth. Results show that zircon shells have characteristic but significantly different Th, U and Pb concentrations. Magmatic zircon from the Vagastie Bridge granite also forms as clearly defined oscillatory zoned shells around unzoned nuclei of inherited zircon. However, the distinction between magmatic and inherited zircon in zircons from the Inchbae granite is less clear. Zircons from the Ben Vuirich granite occur as euhedral, magmatic zircons, or as rounded, subhedral, inherited zircon grains. A SHRIMP age of 597 ± 11 (2σ) Ma for euhedral magmatic zircon from this granite is identical, within the uncertainty, to the conventional multigrain zircon age of 590 ± 2 (2σ) Ma reported by Rogers et al. (1989) and confirms the conclusions of those authors that sedimentation of the Dalradian sequence took place in the Precambrian.

Keywords

geochronologyU-Pb ageszircon ageszircon Th-U-Pb systems in granites
Type
Research Article
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 83 , Issue 1-2: Second Hutton Symposium: The Origin of Granites and Related Rocks , 1992 , pp. 473 - 483
Copyright
Copyright © Royal Society of Edinburgh 1992

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

Black, L. P., Williams, I. S. & Compston, W. 1986. Four zircon ages from one rock: the history of a 3930 Ma-old granulite from Mount Sones, Enderby Land, Antarctica. CONTRIB MINERAL PETROL, 94, 427–37.CrossRefGoogle Scholar
Clayburn, J. A. B., Harmon, R. S., Pankhurst, R. J. & Brown, J. F. 1983. Sr, O, and Pb isotope evidence for origin and evolution of Etive Igneous Complex, Scotland. NATURE 303, 492–7.CrossRefGoogle Scholar
Compston, W., Williams, I. S. & Meyer, C. 1984. U-Pb geochronology of zircons from Lunar breccia 73217 using a sensitive high mass-resolution ion microprobe. Proc. XIV Lunar Planetary Science Conference. J GEOPHYS RES 89, supplement B525.Google Scholar
Compston, W., Williams, I. S., Kirschvink, J. L., Zichao, Zhang & Guogan, Ma 1992. Zircon U-Pb ages for the Early Cambrian time-scale. J GEOL SOC LONDON (in press).Google Scholar
Cumming, G. L. & Richards, J. R. 1975. Ore lead isotope ratios in a continuously changing earth. EARTH PLANET SCI LETT 28, 155–71.CrossRefGoogle Scholar
Halliday, A. N., Aftalion, M., van Breemen, O. & Jocelyn, J. 1979. Petrogenetic significance of Rb-Sr and U-Pb isotopic systems in the 400 Ma old British Isles granitoids and their hosts. GEOL SOC SPEC PUBL 8, 653–61.Google Scholar
Halliday, A. N., Stephens, W. E., Hunter, R. H., Menzies, M. A., Dickin, A. P. & Hamilton, P. J. 1985. Isotopic and chemical constraints on the building of the deep Scottish lithosphere. SCOTT J GEOL 21, 465–91.Google Scholar
Hutton, D. H. W. 1987. Strike-slip terranes and a model for the evolution of the British and Irish Caledonides. GEOL MAG 124, 405–25.Google Scholar
Johnson, M. R. W. & Shepherd, J. 1970. Note on the age of metamorphism of the Moinian. SCOTT J GEOL 6, 228–30.CrossRefGoogle Scholar
Pankhurst, R. J. & Pidgeon, R. T. 1976. Inherited isotope systems and the source region pre-history of early Caledonian Granites in the Dalradian Series of Scotland. EARTH PLANET SCI LETT 31, 3568.CrossRefGoogle Scholar
Piasecki, M. A. J. 1980. New light on the Moine rocks of the Central Highlands of Scotland. J GEOL SOC LONDON 137, 4159.CrossRefGoogle Scholar
Pidgeon, R. T. & Aftalion, M. 1978. Cogenetic and inherited zircon U-Pb systems in Palaeozoic granites from Scotland and England. In Bowes, D. R. & Leake, B. E. (eds) Crustal processes and evolution in N.W. Britain and adjacent regions. GEOL J SPEC ISSUE 10, 183220.Google Scholar
Pidgeon, R. T. & Johnson, M. R. W. 1974. A comparison of zircon U-Pb and whole-rock Rb-Sr systems in three phases of the Cam Chuinneag granite, northern Scotland. EARTH PLANET SCI LETT 24, 105–12.Google Scholar
Read, H. H. 1961. Aspects of Caledonian magmatism in Britain. LIVERPOOL AND MANCHESTER GEOL J 2, 653–83.CrossRefGoogle Scholar
Rogers, G., Dempster, T. J., Bluck, B. J. & Tanner, P. W. G. 1989. A high precision U-Pb age for the Ben Vuirich granite: implications for the evolution of the Scottish Dalradian supergroup. J GEOL SOC LONDON 146, 789–98.CrossRefGoogle Scholar
Shepherd, J. 1973. The structure and structural dating of the Carn Chuinneag Intrusion, Ross-shire. SCOTT J GEOL 9, 6388.CrossRefGoogle Scholar
Steiger, R. H. & Jager, E. 1977. Subcommission on geochronology: convention on the use of decay constants in geo- and cosmochronology. EARTH PLANET SCI LETT 36, 359–62.CrossRefGoogle Scholar
van Breemen, O. & Hawkesworth, C. J. 1980. Sm-Nd isotopic study of garnets and their metamorphic host rocks. TRANS R SOC EDINBURGH EARTH SCI 75, 6570.Google Scholar
van Breemen, O. & Piasecki, M. A. J. 1983. The Glen Kyllachy Granite and its bearing on the nature of the Caledonian Orogeny in Scotland. J GEOL SOC LONDON 140, 4762.CrossRefGoogle Scholar
Williams, I. S., Compston, W., Black, L. P., Ireland, T. R. & Foster, J. J. 1984. Unsupported radiogenic Pb in zircon: a cause of anomalously high Pb-Pb, U-Pb, and Th-Pb ages. CONTRIB MINERAL PETROL 88, 322–7.Google Scholar