Abstract
A combined compositional and Hf, Nd and Sr isotopic study was performed on a suite of samples of progressively deformed granite from a mylonite zone in the Harquahala Mountains, western Arizona, to evaluate the effects of deformation and metamorphism on the isotopic systematics of typical continental crustal rocks. The 1.4 Ga Harquahala Granite was deformed during Mesozoic thrusting along the Harquahala thrust. Granite in the resulting 60 m wide shear zone ranges from protomylonite to ultramylonite. In most of these mylonites, the protolith is not megascopically recognizable, and can be discerned only by the progressive transition to undeformed granite. Isotopic analyses of Hf, Nd and Sr from the shear zone document the immobility of the Hf and Nd isotopic systems relative to that of the Sr isotopic system during deformation. The Rb−Sr isotopic data show considerable scatter on an isochron plot, exhibiting both gains and losses of Rb and Sr from the whole-rock systems. In contrast, the Sm−Nd and Lu−Hf isotopic systematics are mostly well behaved on isochron diagrams, plotting mostly in tight clusters or along 1.4 Ga isochrons. These results show that while the Sr isotopic system in crustal rocks is quite susceptible to later tectonic disturbance, both Hf and Nd isotopic systems can provide reliable model age information in continental crustal terranes even when the rocks have been subjected to low to medium grades of deformation and metamorphism.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Arndt NT, Goldstein SL (1987) Use and abuse of crust-formation ages. Geology 15:893–895
Alderton DHM, Pearce JA, Potts PJ (1980) Rare earth element mobility during granite alteration: evidence from southwest England. Earth Planet Sci Lett 49:149–165
Beach A (1976) The interrelations of fluid transport, deformation, geochemistry and heat flow in early Proterozoic shear zones in the Lewisian complex. Philos Trans R Soc Lond A280:569–604
Blaxland AB (1974) Geochemistry and geochronology of chemical weathering, Butler Hill Granite, Missouri. Geochim Cosmochim Acta 23:843–852
Boullier AM (1980) A preliminary study on the behaviour of brittle minerals in a ductile matrix: example of zircons and feldspars. J Struct Geol 2:211–217
Exley RA (1980) Microprobe studies of REE-rich accessory minerals: implications for Skye Granite petrogenesis and REE mobility in hydrothermal systems. Earth Planet Sci Lett 48:97–110
Fairbairn HW, Hurley PM, Pinson WH Jr (1961) The relation of discordant Rb−Sr mineral and rock ages in an igneous rock to its time of subsequent 87Sr/86Sr metamorphism. Geochim Cosmochim Acta 23:135–144
Farmer GL, DePaolo DJ (1987) Nd and Sr isotope study of hydrothermally altered granite at San Manuel, Arizona: implications for element migration, paths during the formation of porphyry copper ore deposits. Econ Geol 82:1142–1151
Gromet LP, Silver LT (1983) Rare earth element distributions among minerals in a granodiorite and their petrogenetic implications. Geochim Cosmochim Acta 47:925–939
Hall A (1967) The distribution of some major and trace elements in feldspars from the Rosses and Ardara granite complexes, Donegal, Ireland. Geochim Cosmochim Acta 31:835–847
Hanson GN (1978) The application of trace elements to the petrogenesis of igneous rocks of granitic composition. Earth Planet Sci Lett 38:26–43
Hanson GN, Gast PW (1967) Kinetic studies in contact metamorphic zones. Geochim Cosmochim Acta 31:1110–1153
Kerrich R, Allison I, Barnett RL, Moss S, Starkey J (1980) Microstructural and chemical transformations accompanying deformation of granite in a shear zone at Mieville, Switzerland; with implications for stress corrosion cracking and superplastic flow. Contrib Mineral Petrol 73:221–242
Korringa MK, Noble DC (1971) Distribution of Sr and Ba between natural feldspar and igneous melt. Earth Planet Sci Lett 11:147–151
O'Hara K, Blackburn WH (1989) Volume-loss model for traceelement enrichments in mylonites. Geology 17:524–527
Patchett PJ, Ruiz J (1987) Nd isotopic ages of crust formation and metamorphism in the Precambrian of eastern and southern Mexico. Contrib Mineral Petrol 96:523–528
Patchett PJ, Tatsumoto M (1980) A routine high-precision method for Lu−Hf isotope geochemistry and chronology. Contrib Mineral Petrol 75:263–267
Reynolds SJ, Keith SB, Coney PJ (1980) Stacked overthrusts of Precambrian crystalline basement and inverted Paleozoic section emplaced over Mesozoic strata, west central Arizona. In: Jenney JP, Stone C (eds) Studies in western Arizona. Ariz Geol Soc Dig 12:45–52
Richard SM (1988) Bedrock geology of the Harquahala Mountains, west-central Arizona: Mesozoic shear zones, cooling, and Tertiary unroofing. PhD dissertation, University of California Santa Barbara
Rosing MT (1990) The theoretical effect of metasomatism on Sm−Nd isotopic systems. Geochim Cosmochim Acta 54:1337–1342
Smith JV (1974) Feldspar Minerals 2: chemical and textural properties. Springer-Verlag New York
Stevenson RK, Patchett PJ (1990) Implications for the evolution of continental crust from Hf isotope systematics of Archean detrital zircons. Geochim Cosmochim Acta 54:1683–1697
Streckeisen A (1976) To each plutonic rock its proper name. Earth-Sci Rev 12:1–33
Winchester JA, Max MD (1984) Element mobility associated with syn-metamorphic shear zones near Scotchport, NW Mayo, Ireland. J Metamorphic Geol 2:1–11
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Barovich, K.M., Patchett, P.J. Behavior of isotopic systematics during deformation and metamorphism: a Hf, Nd and Sr isotopic study of mylonitized granite. Contr. Mineral. and Petrol. 109, 386–393 (1992). https://doi.org/10.1007/BF00283326
Received:
Accepted:
Issue Date:
DOI: https://doi.org/10.1007/BF00283326