Hostname: page-component-848d4c4894-2pzkn Total loading time: 0 Render date: 2024-05-14T20:10:19.369Z Has data issue: false hasContentIssue false
  • English
  • Français

Experimental approaches to the study of deformation/metamorphism relationships

Published online by Cambridge University Press:  05 July 2018

E. H. Rutter  and
K. H. Brodie
E. H. Rutter
Affiliation:
Geology Department, Imperial College, London SW7 2BP
K. H. Brodie
Affiliation:
Geology Department, Imperial College, London SW7 2BP
Get access Rights & Permissions [Opens in a new window]

Abstract

Rock deformation and metamorphism can interact at the mechanistic level in the following ways: (a) facilitation of cataclasis through the release of high-pressure fluid during dehydration and decarbonation reactions; (b) facilitation of intracrystalline plasticity through the stresses induced during solid-state volume changes; (c) enhanced deformability through the transient existence of fine-grained reaction products; (d) modification of chemical potential gradients driving diffusion if a reaction can occur along the diffusion path; (f) changes in the resistance to intracrystalline plasticity through the effect of reaction-induced changes, pore fluid pressure and chemistry on point defect chemistry of the solid phases.

Examples of experimental studies of each of these types of interaction are described. Special experimental problems arise through: (i) the effects of solid phase and pore space volume changes, and their effects on pore fluid pressure and measured strain; (ii) the effects of such microstructural changes on the determination of flow law parameters; and (iii) in many instances the need for very long duration deformation experiments if reaction kinetics are sluggish.

There is an outstanding need for experimental studies of the effects of non-hydrostatic stress on the conditions for the onset of metamorphic reactions and phase transformations, as a basis for understanding some classes of deformation/metamorphism interaction. However, it is emphasized that the threefold classification of rock deformation mechanisms into cataclastic, crystal-plastic, and diffusive mass transfer processes, established from the study of deformation of monomineralic rocks, forms an essential framework for the understanding of deformation/metamorphism inter-relationships.

Keywords

deformationmetamorphismcataclasisintracrystalline plasticitychemical potential gradients diffusion
Type
Recent Developments in Experimental Petrology and Mineralogy
Information
Mineralogical Magazine , Volume 52 , Issue 364 , March 1988 , pp. 35 - 42
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 1988

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

Barnes, H.L., and Ernst, W.G. (1963) Ideality and ionization in hydrothermal fluids: the system MgOH20- NaOH. Am. J. Sci. 261, 129-50.CrossRefGoogle Scholar
Beach, A. (1982) Deformation mechanisms in some cover thrust sheets from the external French alps. J. Struct. Geol. 4, 41–56.CrossRefGoogle Scholar
Brace, W.F., and Martin, R. (1968) A test of the effective stress law for crystalline rocks of low porosity, lnt. J. Rock Mech. Min. Sci. 5, 415-26.CrossRefGoogle Scholar
Brodie, K.H., and Rutter, E.H. (1985) On the relationship between deformation and metamorphism, with special reference to the behaviour of basic rocks. In Advances in Physical Geochemistry , 4 (A. B. Thompson and D. C. Rubie, eds.), Springer Verlag, N.Y., 138-79.Google Scholar
Brodie, K.H., and Rutter, E.H. (1987) The role of transiently fine-grained reaction products in syntectonic metamorphism: natural and experimental examples. Can. J. Earth Sci. 24, 554–64.CrossRefGoogle Scholar
Bruton, C.J., and Helgeson, H. (1983) Calculation of the chemical and thermodynamic consequences of difference between fluid and geostatic pressure in hydrothermal systems. Am. J. Sci. 283A, 540–88.Google Scholar
Burnley, P.C., and Kirby, S.H. (1982) Pressure-induced embrittlement of polycrystalline tremolite. Trans. Am. Geophys. Union, 63, 1095.Google Scholar
Chopra, P.N., and Paterson, M.S. (1984) The role of water in the deformation of dunite, J. Geophys. Res. 89, 786-17.Google Scholar
Durham, W.B., Heard, H.C., and Kirby, S.H. (1983) Experimental deformation of polycrystalline H2 0 ice at high pressure and low temperature; preliminary results. Ibid. 88(Suppl.), B37792.Google Scholar
Gordon, R.B. (1971) Observation of crystal plasticity under high pressures with applications to the Earth's mantle. Ibid. 76, 124-85.Google Scholar
Greenwood, G.W., and Johnston, R.H. (1965) The deformation of metals under small stresses during phase transformations. Proc. Roy. Soc. Lond. 283A, 403-22.Google Scholar
Greenwood, H.J. (1961) The system NaAISi206-H2 0 Argon: Total pressure and water pressure in metamorphism. J. Geophys. Res. 66, 392-34.Google Scholar
Heard, H.C., and Rubey, W.W. (1966) Tectonic implications of gypsum dehydration. Geol. Soc. Am. Bull., 77 741–60.CrossRefGoogle Scholar
Hobbs, B.E. (1981) The influence of metamorphic environment on the deformation of minerals. Tectonophys. 78, 335–83.CrossRefGoogle Scholar
Hobbs, B.E. (1983) Constraints on the mechanism of deformation of olivine imposed by defect chemistry. Ibid. 92, 35–69.Google Scholar
Karato, S.-I., Paterson, M.S., and Fitzgerald, J.D. (1986) Rheology of synthetic olivine aggregates: Influence of grain-size and water. J. Geophys. Res. 91, 815l76.Google Scholar
Kirby, S.H. (1984) Introduction and digest to the special issue on chemical effects of water on the deformation and strengths of rocks. Ibid. 89, 3991–5.Google Scholar
Kirby, S.H. (1985) Rock mechanics observations pertinent to the rheology of the continental lithosphere and the localization of strain along shear zones. Tectonophys. 119, 127.CrossRefGoogle Scholar
Kronenberg, A.K., and Tullis, 2. A. (1984) Flow strengths of quartz aggregates: grain size and pressure effects due to hydrolytic weakening. J. Geophys. Res. 89,4281–97.CrossRefGoogle Scholar
Murrell, S.A. F., and Ismail, I.A. H. (1976) The effect of decomposition of hydrous minerals on the mechanical properties of rocks. Tectonophys. 31, 207-58.CrossRefGoogle Scholar
Paterson, M.S. (1987) Problems in the extrapolation of laboratory rheological data. Ibid. 133, 3343.Google Scholar
Poirier, J.P. (1982) On transformation plasticity. J. Geophys. Res. 87, 6791–7.CrossRefGoogle Scholar
Raleigh, C.B., and Paterson, M.S. (1965) Experimental deformation of serpentinite and its tectonic implications. Ibid. 70, 3965–85.Google Scholar
Ricoult, D.L., and Kohlstedt, D.L. (1985) Experimental evidence for the effect of chemical environment upon the creep rate of olivine. In Point defects in minerals (R. N. Schock, ed.), Geophys. Monogr. Am. Geoph. Union, 31, 171-84.Google Scholar
Riecker, R., and Rooney, T.P. (1969) Water-induced weakening of hornblende and amphibolite. Nature, 224, 1299.CrossRefGoogle Scholar
Rubie, D.C. (1983) Reaction enhanced ductility; the role of solid-solid univariant reactions in the deformation of the crust and mantle. Tectonophys. 96, 331–52.CrossRefGoogle Scholar
Rutter, E.H. (1972) The influence of water on the rheological behaviour of calcite rocks. Ibid. 14, 1333.Google Scholar
Rutter, E.H. (1974) The influence of temperature, strain-rate and interstitial water in the experimental deformation of calcite rocks. Ibid. 22, 311–34.Google Scholar
Rutter, E.H. (1983) Pressure solution in nature, theory and experiment. J. Geol. Soc. Lond. 140, 725–40.CrossRefGoogle Scholar
Rutter, E.H. and Brodie, K.H. (1987a) The role of tectonic grainsize reduction in the rheological stratification of the lithosphere. Proc. Conf. on Detachment and Shear, Basel, Switzerland. Geol. Rundschau (in press).Google Scholar
Rutter, E.H. (1987b) Experimental ‘syntectonic’ dehydration of serpentinite under controlled pore water pressure (submitted to J. Geophys. Res.). Google Scholar
Rutter, E.H. Peach, C.J., White, S.H., and Johnston, D. (1985) Experimental “syntectonic’ hydration of basalt. J. Struct. Geol. 7, 251–66.CrossRefGoogle Scholar
Sammis, C.G., and Dein, J.L. (1974) On the possibility of transformational superplasticity in the Earth's mantle. J. Geophys. Res. 79, 296-15.Google Scholar
Snow, E., and Yund, R.A. (1987) The effect of ductile deformation on the kinetics and mechanisms of the aragonite-calcite transformation, J. Met. Geol. 5, 141- 53.CrossRefGoogle Scholar
Summers, R., and Byerlee, J.D. (1977) A note on the effect of fault gouge composition on the stability of frictional sliding. Int. J. Rock. Mech. Min. Sci. 14, 155–60.CrossRefGoogle Scholar
Tullis, J.A., Shelton, G.L., and Yund, R.A. (1979) Pressure dependence of rock strength: implications of hydrolytic weakening. Bull. Mineral. 102, 110–14.Google Scholar
White, S.H., and Knipe, R J. (1978) Transformation and reaction enhanced ductility in rocks. J. Geol. Soc. Lond. 135, 513–16.CrossRefGoogle Scholar