Abstract
In the contact aureole of the Lilesville granite and comagmatic Pee Dee gabbro, N.C., greenschist-facies phyllites of the Carolina slate belt have been overprinted by a series of metamorphic reactions producing opx-bearing hornfelses and migmatitic gneisses. In the exterior aureole the slate belt assemblage (chl+ms+ep+ab+qz) gives way to the continuous reaction assemblages (chl+bt+cd+ ms+ab±ep+qz), (bt+cd+ms+An8–29+qz), (bt+cd+ kf+ms+pl+qz), (bt+cd+als±ms+kf+pl+qz), and (bt+cd+ga+kf+pl+qz), from lowest to highest grade. The interior aureole, interpreted as part of the floor of the granite, bears the continuous and discontinuous reaction assemblages (bt+cd+als+kf+pl+qz),(bt+cd+kf+ pl+qz), and, near the gabbro, (bt+cd+ga+opx+kf+ pl+qz). The leucosomes of the migmatitic interior aureole are predominantly trondhjemites with the assemblage (An35–45+qz±bt±cd±kf). Restites in the migmatitic interior aureole contain the AFM assemblages (bt), (bt + cd), (bt+cd+als), and (bt+cd+ga), plus kf, An40–50, and qz. Contact metamorphism was isobaric at 4.0–5.1 or 2.0–3.5 kb depending on choice of aluminosilicate triple point; temperatures reached 650° C in the migmatitic interior aureole and approached 750° C near the gabbro; \({\text{P}}_{{\text{H}}_{\text{2}} {\text{O}}}\) was less than 0.8 in the migmatites, and was lower in the interior aureole and in the high grade exterior aureole. Partial melting in the migmatitic interior aureole took place during dynamothermal metamorphism caused by the magmatic diapir. Incipient melting occurred by the reaction bt+cd+kf+pl+qz+w = liquid. The melt was H2O-undersaturated and coefficients of the reactants were weighted heavily toward the felsic minerals; the proportion of felsic minerals in the leucosomes was controlled in part by modal abundance of kf, pl, and qz available for melting. The incorporation of K into biotite by subsolidus reactions, coupled with the high thermal stability and low solubility of biotite in a felsic melt, are responsible for the trondhjemitic composition of the early anatectic liquids.
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Abbreviations
- als:
-
Al2SiO5
- ab:
-
albite
- An8–29 :
-
plagioclase with anorthite contents in the range indicated
- bt:
-
biotite
- cd:
-
cordierite
- chl:
-
chlorite
- ep:
-
epidote
- ga:
-
garnet
- kf:
-
K feldspar
- ms:
-
muscovite
- opx:
-
orthopyroxene
- pl:
-
plagioclase undefined
- qz:
-
quartz
- w:
-
water
References
Abbott RN Jr, Clarke DB (1979) Hypothetical liquidus relationships in the subsystem Al2O3-FeO-MgO projected from quartz, alkali feldspar and plagioclase for a(H2O)≦1. Can Mineral 17:549–560
Aranovich LYa, Podlesskii KK (1983) The cordierite-garnet-sillimanite-quartz equilibrium: experiments and applications.In: Saxena SK (ed) Kinetics and equilibrium in mineral reactions. Vol 3, Springer-Verlag, Berlin Heidelberg New York, 173–198
Ashworth JR (1976) Petrogenesis of migmatites in the Huntly-Portsoy area, northeast Scotland. Mineral Mag 40:661–682
Blümel P, Schreyer W (1976) Progressive regional low-pressure metamorphism in Moldanubian metapelites of the northern Bavarian forest, Germany. Krystalinikum 12:7–30
Brown GM (1963) Melting relations of Tertiary granitic rocks in Skye and Rhum. Mineral Mag 33:533–562
Butler JR (1972) Age of Paleozoic regional metamorphism in the Carolinas, Georgia, and Tennessee Southern Appalachians. Am J Sci 272:319–333
Butler JR, Fullagar PD (1975) Lilesville and Pageland plutons and the associated meta-rhyolites, eastern Carolina slate belt. Geol Soc Am Abstr with Progr 7:475
Chatterjee ND, Johannes W (1974) Thermal stability and standard thermodynamic properties of synthetic 2M1-muscovite KAl2[AlSi2O10(OH)3]. Contrib Mineral Petrol 48:89–114
Dubrovskiy MI (1982) A physico-chemical (PH2O-T-X) model of mineral assemblages in high-alumina granites. Int Geol Rev 24:955–869
Evans NH (1984) Latest Precambrian to Ordovician metamorphism and orogenesis in the Blue Ridge and western Piedmont, Virginia Appalachians. unpub PhD dissertation, Virginia Polytechnic Institute and State University: p 324
Ferry JM, Spear FS (1978) Experimental calibration of the partitioning of Fe and Mg between biotite and garnet. Contrib Mineral Petrol 66:113–117
Flood RH, Vernon RH (1978) The Cooma granodiorite, Australia: an example of in situ crustal anatexis. Geology 6:81–84
Fullagar PD, Butler JR (1979) 325 to 265 m.y.-old granitic plutons in the Piedmont of the southeastern Appalachians. Am J Sci 279:161–185
Fyfe WS (1970) Some thoughts on granite magmas.In: Newall G, Rast N (eds) Mechanics of Igneous Intrusion. Gallery Press, Liverpool: 201–216
Goldman DS, Albee AL (1977) Correlation of Mg/Fe partitioning between garnet and biotite with 18°/16° partitioning between quartz and magnetite. Am J Sci 277:750–767
Grant JA (1973) Phase equilibria in high-grade metamorphism and partial melting of pelitic rocks. Am J Sci 273:289–317
Hensen BJ (1977) Cordierite-garnet bearing assemblages as geothermometers and barometers in granulite facies terranes. Tectonophysics 43:73–88
Hensen BJ, Green DH (1973) Experimental study of cordierite and garnet in pelitic compositions at high pressures and temperatures. III. Synthesis of experimental data and geological applications. Contrib Mineral Petrol 38:151–166
Hey MH (1954) A new review of the chlorites. Mineral Mag 30:277–292
Hirschberg A, Winkler HGF (1968) Stabilitätsbeziehungen zwischen Chlorit, Chordierit und Almandin bei der Metamorphose. Contrib Mineral Petrol 18:17–42
Hoffer E (1976) The reaction sillimanite+biotite+quartz=cordierite+K-feldspar+H2O and partial melting in the system K2O-FeO-MgO-Al2O3-SiO2-H2O. Contrib Mineral Petrol 55:127–130
Hoffer E (1978) Melting reactions in aluminous metapelities: stability limits of biotite+sillimanite+quartz in the presence of albite. N Jahrb Mineral Monatsh:396–407
Hoffer E, Grant JA (180) Experimental investigation of the formation of cordierite-orthopyroxene parageneses in pelitic rocks. Contrib Mineral Petrol 73:15–22
Holdaway MJ (1971) Stability of andalusite and the aluminum silicate phase diagram. Am J Sci 271:97–131
Johannes W, Gupta LN (1982) Origin and evolution of a migmatite. Contrib Mineral Petrol 79:114–123
Kish SA, Butler JR, Fullagar PD (1979) The timing of metamorphism and deformation in the central and eastern Piedmont of North Carolina. Geol Soc Am Abstr with Progr 11:184–185
Lee SM, Holdaway MJ (1977) Significance of Fe-Mg cordierite stability relations on temperature, pressure, and water pressure in cordierite granulites. Am Geophys Union Monogr 20, AGU, Washington DC: 79–94
Martignole J, Sisi JC (1981) Cordierite-garnet-H2O equilibrium: a geological thermometer, barometer and water fugacity indicator. Contrib Mineral Petrol 77:38–46
Mehnert KR (1968) Migmatites and the origin of granitic rocks. Developments in Petrology, Vol 1. Elsevier Publishing Company, Amsterdam, p 405
Newton RC, Wood BJ (1979) Thermodynamics of water in cordierite and some petrologic consequences of cordierite as a hydrous phase. Contrib Mineral Petrol 68:391–405
Perchuk LL (1977) Thermodynamic control of metamorphic processes.In: Saxena SK, Bhattacharjii S (eds) Energetics of Geological Processes, Springer, New York:285–352
Richardson SW, Gilbert MC, Bell PM (1969) Experimental determination of kyanite-andalusite and andalusite-sillimanite equilibria; the aluminum silicate triple point. Am J Sci 267:259–272
Schmidt AT (1972) Petrology of the Lilesville granite batholith aureole, Anson and Richmond Counties, North Carolina. Master of Science thesis, University of Florida, Gainesville, Florida
Seifert F (1970) Low-temperature compatibility relations of cordierite in haplo-pelites of the system K2O-MgO-Al2O3-SiO2-H2O. J Petrol 11:37–99
Solberg TN, Speer JA (1982) QALL, a 16-element analytical scheme for efficient petrologic work on an automated ARL-SEMQ: Application to mica reference samples. Microbeam Analysis-1982:422–426
Speer JA (1981) The nature and magnetic expression of isograds in the contact aureole of the Liberty Hill pluton, South Carolina. Summary and Part II. Geol Soc Am Bull 92:603–609, 1262–1358
Speer JA (1982) Metamorphism of the pelitic rocks of the Snyder Group in the contact aureole of the Kiglapait layered intrusion, Labrador: effects of buffering partial pressures of water. Can J Earth Sci 19:1888–1909
Speer JA, Becker SW, Farrar SS (1980) Field relations and petrology of the postmetamorphic, coarse-grained granitoids and associated rocks of the Southern Appalachian Piedmont. In: Wones DR (ed) Proceedings “Caledonides in the USA,” IGCP Project 27: Caledonide Orogen, Virginia Polytechnic Institute and State University, Department of Geological Sciences Memoir 2:137–148
Thompson AB (1976a) Mineral reactions in the pelitic rocks: I. Prediction of P-T-X (Fe, Mg) phase relations. Am J Sci 276:401–424
Thompson AB (1976b) Mineral reactions in pelitic rocks: II. Calculations of some P-T-X (Fe, Mg) phase relations. Am J Sci 276:425–454
Thompson AB (1982) Dehydration melting of pelitic rocks and the generation of H2O-undersaturated granitic liquids. Am J Sci 282:1567–1595
Thompson AB, Tracy RJ (1979) Model systems for anatexis of pelitic rocks, II. Facies series melting and reactions in the system CaO-KAIO2-NaAlO2-Al2O3-SiO2-H2O. Contrib Mineral Petrol 70:429–438
Thompson RN (1981) Thermal aspects of the origin of Hebridean Tertiary acid magmas. I. An experimental study of partial fusion of Lewisian gneisses and Torridonian sediments. Mineral Mag 44:161–170
Tuttle OF, Bowen NL (1958) Origin of Granite in the Light of Experimental Studies in the System NaAlSi3O8-KAISi3O8-SiO2-H2O. Geol Soc Am Mem 74
Velde B (1978) High temperature or metamorphic vermiculites. Contrib Mineral Petrol 66:319–323
Waskom JD, Butler JR (1971) Geology and gravity of the Lilesville granite batholith, North Carolina. Geol Soc Am Bull 82:2827–2844
Wedepohl KH (1969) Composition and abundance of common sedimentary rocks. In: Wedepohl KH (ed) Handbook of Geochemistry. Vol 1, Springer, p 442
Whipple ER (1974) A study of Wilson's determination of ferrous iron in silicates. Chem Geol 14:223–238
Winkler HGF, Boese M, Marcopoubs T (1975) Low temperature granitic melts. N Jahrb Mineral Monatsh:245–268
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Evans, N.H., Alexander Speer, J. Low-pressure metamorphism and anatexis of Carolina Slate Belt Phyllites in the contact aureole of the Lilesville Pluton, North Carolina, USA. Contr. Mineral. and Petrol. 87, 297–309 (1984). https://doi.org/10.1007/BF00373062
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DOI: https://doi.org/10.1007/BF00373062