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Deep resistivity imaging across the Northern and Central belts of the Southern Uplands

Published online by Cambridge University Press:  01 May 2009

David Beamish
David Beamish
Affiliation:
British Geological Survey, Keyworth, Nottingham NG12 5GG, UK
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Abstract

Magnetotelluric data from 16 soundings have provided a northwest-southeast traverse across the Northern and Central belts of the Southern Uplands. The 34 km profile extends from the Ordovician Portpatrick Formation (northwest of the Thornhill Basin) across the Silurian Gala Group onto the Permian Lochmaben Basin in the southeast. The survey traverses, and has particular relevance to, the Ordovician/Silurian boundary (Orlock Bridge Fault), the associated Moniaive Shear Zone, and the Moffat Valley Lineament. The data obtained have been successfully modelled (inverted) to provide a crustal-scale resistivity cross-section. The two Upper Palaeozoic basins are resolved as relatively conducting features. Basin depths are about 200 m (Thornhill) and 1100 m (Lochmaben). Elsewhere, through the upper crustal interval, resistivities over 500 ohm m are associated with the Lower Palaeozoic greywackes. The Silurian formations appear more resistive (and slightly thicker) than their Ordovician counterparts. Depth to basement (base Lower Palaeozoic) is not a well-resolved characteristic but resistivity gradients observed below 5 km suggest a depth of this order. Concealed beneath the Thornhill Basin lie two narrow, vertical, conductive zones. The more substantial feature lies towards the northwest margin of the basin, and is probably associated with the Orlock Bridge Fault. The second zone lies towards the southeast margin of the basin. The conductivity minima, in both cases, are located in the depth range 2 to 3 km; they are separate and distinct from the overlying basin sediments. If the two anomalies, some 5 to 6 km apart, can be considered an expression of the Moniaive Shear Zone, then the major conductive constituents are concentrated at the margins. Two dipping, resistive features in the upper kilometre are imaged in the vicinity of the Moffat Valley Lineament.

Type
Articles
Information
Geological Magazine , Volume 132 , Issue 5 , September 1995 , pp. 531 - 538
Copyright
Copyright © Cambridge University Press 1995

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References

Anderson, T. B., & Oliver, G. J. H., 1986. The Orlock Bridge Fault: a major Late Caledonian sinistral fault in the Southern Uplands terrane, British Isles. Transactions of the Royal Society, Edinburgh, Earth Sciences 77, 203–22.CrossRefGoogle Scholar
Bahr, K., 1991. Geological noise in magnetotelluric data: a classification of distortion types. Physics of the Earth and Planetary Interiors 66, 2438.CrossRefGoogle Scholar
Bamford, D., Nann, K., Prodehl, C., & Jacob, B., 1978. LISPB IV. Crustal structure of Northern Britain. Geophysical Journal of the Royal Astronomical Society 54, 4360.Google Scholar
Barnes, R. P., Phillips, E. R., & Boland, M. P., 1995. The Orlock Bridge Fault in the Southern Uplands of southwestern Scotland: a terrane boundary? Geological Magazine 132, 523–9.Google Scholar
Barton, P. J., 1992. LISPB revisited: a new look under the Caledonides of northern Britain. Geophysical Journal International 110, 371–91.Google Scholar
Beamish, D., 1986. Geoelectric structural dimensions: methods of estimation, old and new. Geophysics 51, 12981309.CrossRefGoogle Scholar
Beamish, D., 1991. A whole crust resistivity cross-section across the Ae Forest, Southern Uplands. British Geological Survey Technical Report WN/91/25.Google Scholar
Beamish, D., 1992. Two-dimensional inversion of the Thornhill MT survey data. British Geological Survey Technical Report WN/92/14.Google Scholar
Chave, A. D., & Thomson, D. J., 1989. Some comments on magnetotelluric response function estimation. Journal of Geophysical Research 94, 14215–25.Google Scholar
Degroot-Hedlin, C., & Constable, S., 1990. Occam’s inversion to generate smooth two-dimensional models from magnetotelluric data. Geophysics 55, 1613–24.CrossRefGoogle Scholar
Floyd, J. D., Stone, P., Barnes, R. P., & Lintern, B. C., 1987. Constraints on the significance of the Orlock Bridge Fault within the Scottish Southern Uplands. Transactions of the Royal Society, Edinburgh, Earth Science 78, 219–21.Google Scholar
Hall, J., Powell, D. W., Warner, M. R., El-Hasa, Z. H. M., Adesanya, O., & Bluck, B. J., 1983. Seismological evidence for shallow crystalline basement in the Southern Uplands of Scotland. Nature 305, 418–20.CrossRefGoogle Scholar
Harinarayana, T., Hutton, V. R. S., & Jones, P. C., 1993. Lateral variations of conductivity structure across Southern Scotland and Northern England. Physics of the Earth and Planetary Interiors 81, 25–1.CrossRefGoogle Scholar
Livelybrooks, D., Banks, R. J., Parr, R. S., & Hutton, V. R. S., 1993. Inversion of electromagnetic induction data for the Iapetus Suture Zone in the UK. Physics of the Earth and Planetary Interiors 81, 6784.Google Scholar
Stone, P., Floyd, J. D., Barnes, R. P., & Lintern, B. C., 1987. A sequential back-arc and foreland basin thrust duplex model for the Southern Uplands of Scotland. Journal of the Geological Society, London 144, 753–64.CrossRefGoogle Scholar
Stone, P., Green, P. M., Lintern, B. C., Plant, J. A., Simpson, P. R., & Breward, N., 1991. Geochemistry characterizes provenance in southern Scotland. Geology Today 7, 177–81.Google Scholar
Stone, P., Green, P. M., Lintern, B. C., Simpson, P. R., & Plant, J. A., 1993. Regional geochemical variation across the Iapetus Suture zone: tectonic implications. Scottish Journal of Geology 29, 113–21.Google Scholar