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124 L. BARATOUX ETAL.KNIPE, R. J. 1989. Deformation mechanisms, recognitionfrom natural tectonites. Journal of StructuralGeology, 11, 127-146.KNIPE, R. J. & MCCAIG, A. M. 1994. Microstructuraland microchemical consequences of fluid flow indeforming rocks. In: PARNELL, J. (ed) Geofluids;Origin, Migration and Evolution of Fluids in SedimentaryBasins. Geological Society, London,Special Publications, 78, 99-111.KRETZ, R. 1983. Symbols for rock-forming minerals.American Mineralogist, 68, 277-279.KRONER, A., STIPSKA, P., SCHULMANN, K. &JAECKEL, P. 2000. Chronological constraints onthe pre-Variscan evolution of the northeasternmargin of the Bohemian Massif, Czech Republic.In" FRANKE, W., HAAK, V., ONCKEN, O. &TANNER, D. (eds) Orogenic Processes; Quantificationand Modelling in the Variscan Belt.Geological Society, London, Special Publications,179, 175-197.KRUHL, J. H. 1987. Preferred lattice orientation ofplagioclase from amphibolite and greenschistfacies rocks near the Insubric line (WesternAlps). Tectonophysics, 135, 233-242.KRUSE, R. & STf0NITZ, H. 1999. Deformation mechanismsand phase distribution in mafic hightemperaturemylonites from the Jotun Nappe,southern Norway. Tectonophysics, 303, 223-249.KRUSE, R., STONITZ, H. & KUNZE, K. 2001. Dynamicrecrystallization processes in plagioclase porphyroclasts.Journal of Structural Geology, 23,1781-1802.LAFRANCE, B. & VERNON, R. H. 1993. Mass transferand microfracturing in gabbroic mylonites ofthe Guadalupe igneous complex, California. In:BOLAND, J. N. & FITZ GERALD, J. D. (eds)Defects and Processes in the Solid State;Geoscience Applications; The McLaren Volume.Developments in Petrology, 14, 151-167.LAIRD, J. & ALBEE, A. L. 1981. Pressure, temperature,and time indicators in mafic schists: their applicationto reconstructing the polymetamorphichistory of Vermont. American Journal of Science,281, 127-175.LAPWORTH, T., WHEELER, J. & PRIOR, D. J. 2002.The deformation of plagioclase investigated usingelectron backscatter diffraction crystallographicpreferred orientation data. Journal of StructuralGeology, 24, 387-399.LEAKE, B. E., WOOLLEY, A. R. et aI. 1997. Nomenclatureof amphiboles; report of the subcommittee onamphiboles of the International MineralogicalAssociation, Commission on New Minerals andMineral Names. The Canadian Mineralogist, 35,219-246.LEXA, O. 2003. Numerical approach in structuraland microstructural analyses. PhD thesis, CharlesUniversity, Prague.LISLE, R. J. 1985. The use of the orientation tensor forthe description of statistical fabrics. Journal ofStructural Geology, 7, 115-117.LISTER, G. S., PATERSON, M. S. & HOBBS, B. E. 1978.The simulation of fabric development in plasticdeformation and its application to quartzite; themodel. Tectonophysics, 45, 107-158.MARSHALL, D. B. & MCLAREN, A. C. 1977a. Deformationmechanisms in experimentally deformedplagioclase feldspars. Physics and Chemistry ofMinerals, 1,351-370.MARSHALL, D. B. & MCLAREN, A. C. 1977b. Thedirect observation and analysis of dislocations inexperimentally deformed plagioclase feldspars.Journal of Material Science, 12, 893-903.MARTELAT, J. E., SCHULMANN, K., LARDEAUX, J. M.,NICOLLET, C. & CARDON, H. 1999. Granulite microfabricsand deformation mechanisms in southernMadagascar. Journal of Structural Geology, 21,671-687.MAULER, A., GODARD, G. & KUNZE, K. 2001. Crystallographicfabrics of omphacite, rutile and quartzin Vendee eclogites (Armorican Massif, France);consequences for deformation mechanisms andregimes. Tectonophysics, 342, 81 - 112.McCAI6, A. M. & KNIPE, R. J. 1990. Mass-transportmechanisms in deforming rocks; recognitionusing microstructural and microchemical criteria.Geology, 18, 824-827.MEANS, W. D. 1990. Kinematics, stress, deformationand material behavior. Journal of StructuralGeology, 12, 953-971.MONTARDI, Y. & MAINPRICE, D. 1987. A transmissionelectron microscopy study of the natural plasticdeformation of calcic plagioclases (An 68-70).Bulletin de Mineralogie, 110, 1-14.MORRISON-SMITH, D. J. 1976. Transmission electronmicroscopy of experimentally deformed hornblende.American Mineralogist, 61, 272-280.NYMAN, M. W., LAW, R. D. & SMELIK, E. A. 1992.Cataclastic deformation mechanism for the developmentof core-mantle structures in amphibole.Geology, 20, 455-458.OLSEN, T. S. & KOHLSTEDT, D. L. 1984. Analysis ofdislocations in some naturally deformed plagioclasefeldspars. Physics and Chemistry of Minerals,11, 153-160.OLSEN, T. S. & KOHLSTEDT, D. L. 1985. Naturaldeformation and recrystallization of some intermediateplagioclase feldspars. Tectonophysics,111, 107-131.ORD, A. & HOBBS, B. E. 1989. The strength of the continentalcrust, detachment zones and the developmentof plastic instabilities. Tectonophysics, 158,269-289.PANOZZO, R. H. 1983. Two-dimensional analysis ofshape-fabric using projections of digitized lines ina plane. Tectonophysics, 95, 279-294.POIRIER, J. P. & GUILLOPt~, M. 1979. Deformationinduced recrystallization of minerals. Bulletin deMindralogie, 102, 67-74.PRIOR, D. J. & WHEELER, J. 1999. Feldspar fabrics in agreenschist facies albite-rich mylonite from electronbackscatter diffraction. Tectonophysics, 303,29 -49.PRIOR, D. J., BOYLE, A. P. et al. 1999. The applicationof electron backscatter diffraction and orientationcontrast imaging in the SEM to textural problemsin rocks. American Mineralogist, 84, 1741-1759.276
TEXTURES OF NATURALLY DEFORMED METAGABBROS 125ROONEY, T. P., RIECKER, R. E. & Ross, M. 1970.Deformation twins in hornblende. Science, 169,173-175.ROONEY, T. P., RIECKER, R. E. & GAVASCI, A. T.1975. Hornblende deformation features. Geology,3, 364-366.ROSENBERG, C. L. & STONITZ, H. 2003. Deformationand recrystallization of plagioclase along atemperature gradient: An example from theBergell tonalite. Journal of Structural Geology,25, 389-408.RUTTER, E. H. & BRODIE, K. H. 1988. Experimental'syntectonic' dehydration of serpentinite underconditions of controlled pore water pressure.Journal of Geophysical Research, B, 93, 4907-4932.RUTTER, E. H. 8,: BRODIE, K. H. 1992. Rheology of thelower crust. In: FOUNTAIN, D. M., ARCULUS, R. &KAY, R. W. (eds) Continental Lower Crust. Developmentsin Geotectonics, Elsevier, Amsterdam, 23,201-267.SCHULMANN, K., ML(~OCH, B. 8,: MELKA, R. 1996.High-temperature microstructures and rheology ofdeformed granite, Erzgebirge, Bohemian Massif.Journal of Structural Geology, 18, 719-733.SODRE-BORGES, P. & WHITE, S. H. 1980. Microstructuraland chemical studies of sheared anorthasites,Roneval, South Harris. Journal of StructuralGeology, 2, 273-280.SIMPSON, C. 1985. Deformation of granitic rocksacross the brittle ductile transition. Journal ofStructural Geology, 7, 503-511.SKROTZKI, W. 1990. Microstructure in hornblende of amylonitic amphibolite. In: Knipe ROBERT, J. &RUTTER, E. H. (eds) Deformation Mechanisms,Rheology and Tectonics. Geological Society,London, Special Publications, 54, 321-325.SPRY, A. 1969. Metamorphic Textures. PergamonPress, Oxford.STiPSKA, P., SCHULMANN, K., THOMPSON, A. B.,JE~EK, J. & KRONER, A. 2001. Thermo-mechanicalrole of a Cambro-Ordovician paleorift during theVariscan collision; the NE margin of the BohemianMassif. Tectonophysics, 332, 239-253.STfPSKA, P., SCHULMANN, K. & KRONER, A. 2004.Vertical extrusion and middle crustal spreading ofomphacite granulite: a model of synconvergentexhumation (Bohemian Massif, Czech Republic).Journal of Metamorphic Geology, 22, 179-198.ST15NITZ, H. & F/TZ GERALD, J. D. 1993. Deformationof granitoids at low metamorphic grade; II, Granularflow in albite-rich mylonites. Tectonophysics,221, 299-324.STUNITZ, H. FITZ GERALD, J. D. & TULLIS, J. 2003.Dislocation generation, slip systems, and dynamicrecrystallization in experimentally deformedplagioclase single crystals. Tectonophysics, 372,215-233.SUN, S. S. & MCDONOUGH, W. F. 1989. Chemical andisotopic systematics of oceanic basalts; implicationsfor mantle composition and processes. In:SAUNDERS, A. D. & NORRY, M. J. (eds) Magmatismin the Ocean Basins. Geological Society,London, Special Publications, 42, 313-345.TULLIS, J. 1983. Deformation of feldspars. In:RmBE, P. H. (ed) Feldspar Mineralogy. Reviewsin Mineralogy. Mineralogical Society of America,Washington, DC, 2, 297-323.TULLIS, J. & YUND, R. A. 1987. Transition fromcataclastic flow to dislocation creep of feldspar;mechanisms and microstructures. Geology, 15,606-609.TULLIS, J. & YUND, R. A. 1991. Diffusion creepin feldspar aggregates; experimental evidence.Journal of Structural Geology, 13, 987-1000.TULLIS, J. & YUND, R. 1992. The brittle-ductile transitionin feldspar aggregates; an experimentalstudy. In: EVANS, B. & WONG TENG, F. (eds)Fault Mechanics and Transport Properties ofRocks; A Festschrift in Honor of W. F. Brace. AcademicPress, San Diego, United States, 89-117.VERNON, R. H. 1976. Metamorphic Processes. Murby,London, Wiley, New York.VOLL, G. 1976. Recrystallization of quartz, biotite andfeldspars from Erstfeld to the Leventina Nappe,Swiss Alps, and its geological significance. SchweizerischeMineralogische und PetrographischeMitteilungen, 56, 641-647.WALKER, A. N., RUTTER, E. H. & BRODIE, K. H. 1990.Experimental study of grain-size sensitive flow ofsynthetic, hot-pressed calcite rocks. In: KNIPE, R. J.& RUTTER, E. H. (eds) Deformation Mechanisms,Rheology and Tectonics. Geological Society,London, Special Publications, 54, 259-284.WILKS, K. R. • CARTER, N. L. 1990. Rheology ofsome continental lower crustal rocks. Tectonophysics,182, 57-77.YUND, R. & TULLIS, J. 1991. Compositional changesof minerals associated with dynamic recrystallization.Contributions to Mineralogy and Petrology,108, 346-355.ZUCALI, M., CHATEIGNER, D., DUGNANI, M.,LETTEROTTI, L. & OULADDIAF, B. 2002. Quantitativetexture analysis of glaucophanite deformedunder eclogite facies conditions (Sesia-Lanzozone, Western Alps): comparison between X-rayand neutron diffraction analysis. In: DE MEER, S.,DRURY, M. R., DE BRESSER, J. H. P. &PENNOCK, G. M. (eds) Deformation Mechanisms,Rheology and Tectonics: Current Status andFuture Perspectives. Geological Society, London,Special Publications, 200, 219-238.277
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Contentsviii4.7 Schulmann, Konopás
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Dedicated to my wife Markéta, daug
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Foreword 2First topic “Quantitati
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Foreword 4source and freely availab
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1. Quantitative analysis of deforma
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Chapter 2Mechanisms of lower crusta
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2. Mechanisms of lower crustal flow
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Chapter 3Quantitative analyses ofme
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3. Quantitative analyses of metamor
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Bibliography 42Culshaw, N., Beaumon
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Bibliography 44sources and trigger
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Bibliography 46Skrzypek, E., Štíp
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Table 1Statistical values of the qu
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Table 2Summary of parameters derive
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J. metamorphic Geol., 2008, 26, 273
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EXHUMATION IN LARGE HOT OROGEN 275m
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Probabi l irequencyProbabi l ireque
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EXHUMATION IN LARGE HOT OROGEN 279y
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EXHUMATION IN LARGE HOT OROGEN 281N
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EXHUMATION IN LARGE HOT OROGEN 283w
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EXHUMATION IN LARGE HOT OROGEN 285a
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EXHUMATION IN LARGE HOT OROGEN 287w
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EXHUMATION IN LARGE HOT OROGEN 289T
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EXHUMATION IN LARGE HOT OROGEN 291O
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EXHUMATION IN LARGE HOT OROGEN 293r
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EXHUMATION IN LARGE HOT OROGEN 295B
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EXHUMATION IN LARGE HOT OROGEN 297R
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HEAT SOURCES AND EXHUMATION MECHANI
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ORIGIN OF FELSIC MIGMATITES 41(a)(b
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ORIGIN OF FELSIC MIGMATITES 43(a)(b
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ORIGIN OF FELSIC MIGMATITES 45Fig.
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ORIGIN OF FELSIC MIGMATITES 47produ
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ORIGIN OF FELSIC MIGMATITES 49stron
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ORIGIN OF FELSIC MIGMATITES 51Cmı
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ORIGIN OF FELSIC MIGMATITES 53easte
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104 J. FRANĚK ET AL.in terms of th
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106 J. FRANĚK ET AL.Fig. 2. Struct
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126 J. FRANĚK ET AL.development of
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128 J. FRANĚK ET AL.Behrmann, J.H.
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130 J. FRANĚK ET AL.Southern Bohem
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