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Granite emplacement mechanisms and tectonic controls: inferences from deformation studies

Published online by Cambridge University Press:  03 November 2011

Donald H. W. Hutton
Donald H. W. Hutton
Affiliation:
Department of Geological Sciences, Durham University, Durham DH1 3LE, U.K.
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Abstract

This paper is a structural and tectonic approach to the emplacement and deformation of granitoids. The main methods available in structural geology are briefly reviewed and this emphasises that (a) a wealth of data, particularly strain and shear sense, which pertain to these problems, can be determined in and around plutons; (b) given the nature, unlike many other crustal rock types, of granites to crystallise from isotropic through weakly anisotropic crystal suspension fluids, that deformation which has occurred in these states may not be well preserved; and (c) it is entirely possible, using this methodology, to separate deformation resulting from externally originating tectonic stresses from that which is associated with internal magma-related stresses. It is also recommended that the genetically-based Cloosian classification of granite fabrics and structures into “primary” (magmatic flow/magmatic flow current) and “secondary”, be abandoned and that a more observationally-based approach which classifies granite deformation fabrics and structures according to their time of occurrence relative to the crystallisation state of the congealing magma, be adopted (i.e. pre-full crystallisation deformation and crystal plastic strain deformation).

Examples of recent, structurally based, studies of emplacement mechanisms of plutons within tectonic settings are described and these show that, in general, space for magma can be created by the combination of tectonically-created cavities and internal magma-related buoyancy. This occurs in both transcurrent and extensional tectonic settings and there is no reason to doubt that it can happen in compressive-contractional regimes. It is concluded that transient and permanent space creation, such as may be exploited by available magmas, is a typical feature of the tectonically stressed and deforming lithosphere and this, in combination with the natural buoyancy and ascending tendency of magmas, can generate the varied emplacement mechanisms of granites.

Keywords

magma rheologystraintectonics
Type
Research Article
Information
Earth and Environmental Science Transactions of The Royal Society of Edinburgh , Volume 79 , Issue 2-3: The Origin of Granites , 1988 , pp. 245 - 255
Copyright
Copyright © Royal Society of Edinburgh 1988

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References

Anderson, E. M. 1936. The dynamics of the formation of conesheets, ring dykes, and cauldron subsidence. PROC R SOC EDINBURGH 56, 128163.CrossRefGoogle Scholar
Anderson, D. L. 1981. Rise of deep diapirs. GEOLOGY 9, 79.Google Scholar
Arzi, A. A. 1978. Critical phenomena in the rheology of partially melted rocks. TECTONOPHYSICS 44, 173184.CrossRefGoogle Scholar
Balk, R. 1937. Structural behaviour of igneous rocks. MEM GEOL SOC AM 5, 177 pp.Google Scholar
Bateman, R. 1984. On the role of diapirism in the segregation, ascent and final emplacement of granitoids. TECTONOPHYSICS 110, 211231.Google Scholar
Berger, A. R. 1971. The origin of banding in the Main Donegal Granite, N.W. Ireland. GEOL J 7, 347358.Google Scholar
Berger, A. R. & Pitcher, W. S. 1970. Structures in granitic rocks. A commentary and a critique on granite tectonics. PROC GEOL ASSOC LONDON 81, 441461.CrossRefGoogle Scholar
Berthe, D., Choukroune, P. & Jegouzo, P. 1979. Orthogeneiss, mylonites and non coaxial deformation of granites: the example of the South Armorican shear zone. J STRUCT GEOL 1, 3142.Google Scholar
Bouchez, J. L., Lister, G. S. & Nicolas, A. 1983. Fabric asymmetry and shear sense in movement zones. GEOL RUNDSCH 72, 401419.CrossRefGoogle Scholar
Brun, J. P. & Pons, J. 1981. Strain patterns of pluton emplacement in a crust undergoing noncoaxial deformation. J STRUCT GEOL 3, 219229.CrossRefGoogle Scholar
Buddington, A. F. 1959. Granite emplacement with special reference to North America. BULL GEOL SOC AM 70, 671747.CrossRefGoogle Scholar
Castro, A. 1984. Emplacement fractures in granite plutons (Central Extramadura batholith, Spain). GEOL RUNDSCH 73, 869880.CrossRefGoogle Scholar
Castro, A. 1986. Structural pattern and ascent model in the Central Extramadura batholith, Hercynian belt, Spain. J STRUCT GEOL 8, 633645.CrossRefGoogle Scholar
Choukroune, P., Gapais, D. & Merle, O. 1987. Shear criteria and structural symmetry. J STRUCT GEOL 9, 525530.CrossRefGoogle Scholar
Cooper, M. A. & Bruck, P. M. 1983. Tectonic relationships of the Leinster Granite, Ireland. GEOL J 18, 351360.CrossRefGoogle Scholar
Courrioux, G. 1982. Exemple de mise en place d'un leucogranite pendant le fonctionnement d'une zone de cissaillement: le granite hercynien de Puentedeume (Galice, Espagne). BULL SOC GEOL FR 25, 301307.Google Scholar
Courrioux, G. 1987. Oblique diapirism: the Criffel granodiorite/granite zoned pluton (southwest Scotland). J STRUCT GEOL 9, 313330.CrossRefGoogle Scholar
Coward, M. P. 1976. Strain within ductile shear zones. TECTONOPHYSICS 28, 89124.Google Scholar
Davies, F. B. 1982. Pan-African granite intrusion in response to tectonic volume changes in a ductile shear zone from northern Saudi Arabia. J GEOL 90, 467483.CrossRefGoogle Scholar
Dixon, J. M. & Simpson, D. G. 1987. Centrifuge modelling of laccolith intrusion. J STRUCT GEOL 9, 87103.CrossRefGoogle Scholar
Flinn, D. 1965. On the symmetry principle and the deformation ellipsoid. GEOL MAG 102, 3645.Google Scholar
Fry, N. 1979a. Density distribution techniques and strained length methods for determination of finite strains. J STRUCT GEOL 1, 221229.CrossRefGoogle Scholar
Fry, N. 1979b. Random point distributions and strain measurements in rocks. TECTONOPHYSICS 60, 89105.Google Scholar
Gibbs, A. D. 1984. Structural evolution of extensional basin margins. J GEOL SOC LONDON 141, 608620.Google Scholar
Guineberteau, B., Bouchez, J-L., & Vigneresse, J-L. 1987. The Mortagne granite pluton (France) emplaced by pull-apart along a shear zone: structural and gravimetric arguments, regional implication. BULL GEOL SOC AM (in press).2.0.CO;2>CrossRefGoogle Scholar
Hall, A. 1987. Igneous Petrology London: Longman.Google Scholar
Hanmer, S. 1981. Tectonic significance of the northeastern Gander Zone, Newfoundland: an Acadian ductile shear zone. CAN J EARTH SCI 18, 120135.CrossRefGoogle Scholar
Hanna, S. S. & Fry, N. 1979. A comparison of methods of strain determination in rocks from southwest Dyfed (Pembrokeshire) and adjacent areas. J STRUCT GEOL 1, 155162.CrossRefGoogle Scholar
Hibbard, M. J. 1987. Deformation of incompletely crystallised magma systems: granitic gneisses and their tectonic implications. J GEOL 95, 543561.Google Scholar
Holder, M. T. 1979. An emplacement mechanism for post-tectonic granites and its implication for their geochemical features. In Atherton, M. P. & Tarney, O. O. (eds) Origin of granite batholiths: geochemical evidence, 116128. Nantwich: Shiva.CrossRefGoogle Scholar
Hollister, L. & Crawford, M. L. 1986. Melt-enhanced deformation: a major tectonic process. GEOL 14, 558561.2.0.CO;2>CrossRefGoogle Scholar
Hutton, D. H. W. 1977. A structural cross-section from the aureole of the Main Donegal granite GEOL J 12, 99112.CrossRefGoogle Scholar
Hutton, D. H. W. 1982a. A tectonic model for the emplacement of the Main Donegal granite, NW Ireland. J GEOL SOC LOND 139, 615631.Google Scholar
Hutton, D. H. W. 1982b. A method for the determination of the initial shapes of deformed xenoliths in granitoids. TECTONOPHYSICS 85, T4550.Google Scholar
Hutton, D. H. W. 1988. Igneous emplacement in a shear zone termination: the biotite granite at Strontian, Scotland. BULL GEOL SOC AM (in press).2.3.CO;2>CrossRefGoogle Scholar
Hutton, D. H. W. & Dewey, J. F. 1986. Paleozoic terrane accretion in the western Irish Caledonides. TECTONICS 5, 11151124.CrossRefGoogle Scholar
Leake, B. E. 1978. Granite emplacement: the granites of Ireland and their origin. In Bowes, D. R. & Leake, B. E. (eds) Crustal evolution in northwestern Britain and adjacent regions. GEOL J SPEC PUBL 10, 221248.Google Scholar
Lister, G. S. & Hobbs, B. E. 1980. The simulation of fabric development during plastic deformation and its application to quartzite: the influence of deformation history. J STRUCT GEOL 2, 355370.CrossRefGoogle Scholar
Marre, J. 1986. The structural analysis of granitic rocks. Oxford: North Oxford Academic.Google Scholar
Marsh, B. D. 1982. On the mechanics of igneous diapirism, stoping and zone melting. AM J SCI 282, 808855.CrossRefGoogle Scholar
Miller, C. F., Watson, E. B. & Harrison, T. M. 1988. Perspectives on the source, segregation and transport of granitoid magmas. TRANS R SOC EDINBURGH EARTH SCI 79, 135156.Google Scholar
Munro, M. 1965. Some structural features of the Caledonian granitic complex at Strontian, Argyllshire. SCOTT J GEOL 1, 152175.CrossRefGoogle Scholar
Munro, M. 1973. Structures in the south-eastern portion of the Strontian granitic complex, Argyllshire. SCOTT J GEOL 9, 99108.Google Scholar
Murphy, F. C. 1987. Late Caledonian granitoids and timing of deformation in the Iapetus suture zone of eastern Ireland. GEOL MAG 124, 135142.Google Scholar
Murrell, S. A. F. 1970. Global tectonics, rock mechanics, and the mechanism of volcanic intrusions. In Newall, G., & Rast, N. (eds) Mechanisms of igneous intrusion. GEOL J SPEC PUBL 2, 231244.Google Scholar
Natal'in, B. A., Parfenov, L. M., Vrubleusky, A. A., Karsakov, L. P., & Yushmanov, V. V. 1986. Main fault systems of the Soviet Far East. In Reading, H. G., Watterson, J., & White, S. H. (eds) Major crustal lineaments and their influence on the geological history of the continental lithosphere, 267275. London: Royal Society of London.Google Scholar
Passchier, C. W. & Simpson, C. 1986. Porphyroclast systems as kinematic indicators. J STRUCT GEOL 8, 831843.CrossRefGoogle Scholar
Pitcher, W. S. 1952. The Rosses granitic ring complex, County Donegal, Eire. PROC GEOL ASSOC LONDON 64, 153183.CrossRefGoogle Scholar
Pitcher, W. S. & Berger, A. R. 1972. The geology of Donegal: a study of granite emplacement and unroofing. London: Wiley Interscience.Google Scholar
Pitcher, W. S. & Bussell, M. A. 1977. Structural control of batholith emplacement in Peru: a review. J GEOL SOC LOND 133, 249256.Google Scholar
Platt, J. P. & Vissers, R. L. M. 1980. Extensional structures in anisotropic rocks. J STRUCT GEOL 2, 397410.CrossRefGoogle Scholar
Pollard, D. D. & Johnston, A. M. 1973. Mechanics of growth of some laccolithic intrusions in the Henry mountains, Utah-II. Bending and failure of overburden layers and sill formation. TECTONOPHYSICS 18, 311345.Google Scholar
Ramsay, J. G. & Graham, R. H. 1970. Strain variation in shear belts. CAN J EARTH SCI 7, 786813.CrossRefGoogle Scholar
Ramsay, J. G. & Huber, M. I. 1983. The techniques of modern structural geology, Volume 1: strain analysis. London: Academic Press.Google Scholar
Read, H. H. 1957. The Granite Controversy. London: Thomas Murby & Co.Google Scholar
Roberts, J. L. 1970. The intrusion of magma into brittle rocks. In Newall, G. & Rast, N. (eds) Mechanisms of igneous intrusion. GEOL J SPEC PUBL 2, 287338.Google Scholar
Robson, G. R. & Barr, K. G. 1963. The effect of stress on faulting and minor intrusions in the vicinity of a magma body. I.U.G.G. 13, 315330.Google Scholar
Sabine, P. A. 1963. The Strontian granite complex, Argyllshire. BULL GEOL SURV GB 20, 642.Google Scholar
Saltzer, S. D. & Hodges, K. V. 1988. The Middle Mountain shear zone, southern Idaho: Kinematic analysis of an early Tertiary high temperature detachment. BULL GEOL SOC AM 100, 96103.Google Scholar
Sanderson, D. J. 1976. The superposition of compaction and plane strain. TECTONOPHYSICS 30, 3554.Google Scholar
Sanderson, D. J. & Marchini, D. 1984. Transpression. J STRUCT GEOL 6, 449458.Google Scholar
Sanderson, D. J. & Meneilly, A. W. 1981. Strain modified uniform distributions: andalusites from a granite aureole. J STRUCT GEOL 3, 109116.CrossRefGoogle Scholar
Shaw, H. R. 1980. The fracture mechanisms of magma transport from the mantle to the surface. In Hargreaves, R. B. (ed.) Physics of magmatic processes, 201264. Princeton, N. J: Princeton Press.Google Scholar
Sibson, R. H. 1986. Earthquakes and lineament infrastructure. In Reading, H. G., Watterson, J. & White, S. H. (eds) Major crustal lineaments and their influence on the geological history of the continental lithosphere, 6379. London: Royal Society of London.Google Scholar
Simpson, C. & Schmid, S. M. 1983. An evaluation of criteria to deduce the sense of movement in sheared rocks. BULL GEOL SOC AM 94, 1291–1288.2.0.CO;2>CrossRefGoogle Scholar
Soper, N. J. & Hutton, D. H. W. 1984. Late Caledonian sinistral displacements in Britain: implications for a three plate collision model. TECTONICS 3, 781794.CrossRefGoogle Scholar
Talbot, C. J. 1970. The minimum strain ellipsoid using deformed quartz veins. TECTONOPHYSICS 9, 4776.CrossRefGoogle Scholar
Van der Molen, I. & Peterson, M. S. 1979. Experimental deformation of partly-melted granite. CONTRIB MINERAL PETROL 70, 299318.CrossRefGoogle Scholar
White, N. & Hutton, D. H. W. 1985. The structure of the Dalradian rocks in west Fanad, County Donegal. IR J EARTH SCI 7, 7992.Google Scholar
White, S. H., Brefan, P. G. & Rutter, E. H. 1986. Fault zone reactivation: kinematics and mechanisms. In Reading, H. G., Watterson, J. & White, S. H.Major crustal lineaments and their influence on the geological history of the continental lithosphere, 8197. London: Royal Society of London.Google Scholar
Woodcock, N. H. & Underhill, J. R. 1987. Emplacement related fault patterns around the Northern Granite; Arran, Scotland. BULL GEOL SOC AM 98, 515527.2.0.CO;2>CrossRefGoogle Scholar