DOCSLIB.ORG

Geochemical Characteristics of Crustal Anatexis During the Formation of Migmatite at the Southern Sierra Nevada, California

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Geochemical Characteristics of Crustal Anatexis During the Formation of Migmatite at the Southern Sierra Nevada, California Contrib Mineral Petrol (2005) DOI 10.1007/s00410-005-0010-2 ORIGINAL PAPER Lingsen Zeng Æ Jason B. Saleeby Æ Mihai Ducea Geochemical characteristics of crustal anatexis during the formation of migmatite at the Southern Sierra Nevada, California Received: 6 October 2003 / Accepted: 10 March 2005 Ó Springer-Verlag 2005 Abstract We provide data on the geochemical and iso- tively high Rb, Pb, Ba, and K2O contents, Rb/Sr ratios topic consequences of nonmodal partial melting of a (0.15<Rb/Sr<1.0), and initial eNd values . Group B thick Jurassic pelite unit at mid-crustal levels that pro- leucosomes have relatively low Rb, Pb, Ba, and K2O duced a migmatite complex in conjunction with the contents, Rb/Sr ratios (<0.15), and initial eNd values. intrusion of part of the southern Sierra Nevada batho- The low Rb concentrations and Rb/Sr ratios of the lith at ca. 100 Ma. Field relations suggest that this pelitic group B leucosomes together suggest that partial melting migmatite formed and then abruptly solidified prior to was dominated by water-saturated or H2O-fluxed melt- substantial mobilization and escape of its melt products. ing of quartz + feldspar assemblage with minor Hence, this area yields insights into potential mid-crustal involvement of muscovite. Breakdown of quartz and level contributions of crustal components into Cordil- plagioclase with minor contributions from muscovite leran-type batholiths. Major and trace-element analyses resulted in low Rb/Sr ratios characterizing both group A in addition to field and petrographic data demonstrate and group B leucosomes. In contrast, group A leuco- that leucosomes are products of partial melting of the somes have greater contributions from K-feldspar, pelitic protolith host. Compared with the metapelites, which is suggested by: (1) their relatively high K con- leucosomes have higher Sr and lower Sm concentrations centrations, (2) positive or slightly negative Eu anoma- and lower Rb/Sr ratios. The initial 87Sr/86Sr ratios of lies, and (3) correlation of their Pb and Ba leucosomes range from 0.7124 to 0.7247, similar to those concentrations with K2O contents. It is also shown that of the metapelite protoliths (0.7125–0.7221). However, accessory minerals have played a critical role in regu- the leucosomes have a much wider range of initial eNd lating the partitioning of key trace elements such as Sm, values, which range from À6.0 to À11.0, as compared to Nd, Nb, and V between melt products and residues À8.7 to À11.3 for the metapelites. Sr and Nd isotopic during migmatization. The various degrees of parent/ compositions of the leucosomes, migmatites, and daughter fractionations in the Rb–Sr and Sm–Nd iso- metapelites suggest disequilibrium partial melting of the topic systems as a consequence of nonmodal crustal metapelite protolith. Based on their Sr, Nd, and other anatexis would render melt products with distinct iso- trace-element characteristics, two groups of leucosomes topic signatures, which could profoundly influence the have been identified. Group A leucosomes have rela- products of subsequent mixing events. This is not only important for geochemical patterns of intracrustal dif- ferentiation, but also a potentially important process in Communicated by Ian Carmichael generating crustal-scale as well as individual pluton- scale isotopic heterogeneities. L. Zeng (&) Æ J. B. Saleeby Division of Geological and Planetary Sciences, California Institute of Technology, Pasadena, CA 91125, USA E-mail: [email protected] Tel.: +86-10-68992875 Fax: +86-10-68994781 Introduction M. Ducea The origin of geochemical and isotopic heterogeneities Department of Geological Sciences, University of Arizona, Tucson, AZ 85721, USA of large granitic batholiths is a fundamental question with regard to granitoid petrogenesis and the evolution L. Zeng Key Laboratory for Continental Dynamics, MLR, of the continental crust (Fyfe 1973; Miller et al. 1988; Institute of Geology, Chinese Academy of Geological Sciences, Sawyer 1998). Heterogeneity in the initial radiogenic Beijing 100037, China isotopic compositions of granitic plutons is commonly attributed to heterogeneities inherited from source re- ponents into Cordilleran-type batholiths. In this paper, gimes and preserved due to incomplete mixing of the we intend to address (1) the geochemical nature of the derivative magma. However, contamination of granitic melting products from the metapelite, (2) the magnitude magmas by assimilation of anatectic melts of wallrocks of isotopic heterogeneity produced by such crustal during ascent could also profoundly affect the geo- anatexis, (3) elemental and isotopic fractionations asso- chemical and isotopic character of the final products. ciated with the formation of the migmatites, and (4) The role of crustal anatexis at various crustal levels in implications for the intracrustal differentiation and iso- generating geochemical and isotopic heterogeneities is topic heterogeneities within Cordilleran-type batholiths. poorly understood. Thus, characterization of the geo- The nomenclature used in this paper follows that of chemical and isotopic nature of anatectic melts in high- Johannes (1988). Leucosome is the leucogranitic portion grade metamorphic terrains would help to better formed during migmatization, and the melanosome is the understand the sources of such heterogeneity and their mafic-rich selvage between the leucosome and meso- potential magnitude. some. Mesosome has intermediate color between the Recent experimental and field observations have leucosome and melanosome in a migmatite and differ- shown that partial melting at crustal levels is commonly entiates into leucosome and melanosome during mig- nonmodal (Vielzeuf and Holloway 1988; Le Breton and matization. The rock undergoing migmatization is called Thompson 1988; Rushmer 1991; Puziewicz and Johan- the parent rock, which in the nonmigmatitic far field is nes 1990; Inger and Harris 1993; Dardien et al. 1995; also referred to as the protolith. Harris et al. 1995) and produces melts with isotopic compositions that are in disequilibrium with respect to their sources (Tomomasini and Davies 1997; Knesel and Davidson 2002). Disequilibrium melting refers to any Geologic setting melting event where the liquid phase was not in chemical or isotopic equilibrium with the residue prior to melt Metamorphic rocks of the Isabella pendant consist of a extraction. Nonmodal melting is the melting process stratified sequence of pelitic and psammitic schist and where the proportion of reactant phases in the source is gneiss, quartzite, marble, and calc–silicate rock. This different from their proportions entering the melt. sequence of stratified rocks constitutes one of the best Crustal anatexis in response to thermal or chemical preserved sections through the early Mesozoic Kings perturbations is complex, depending on the temperature sequence, which constitutes a distinct family of pendants and pressure conditions, mineral compositions, and that runs for over 250 km along the axis of the southern water contents. Following a given temperature trajec- Sierra Nevada batholith (Saleeby and Bushy 1993). The tory and for mica-bearing metasedimentary rocks, entire pendant reached amphibolite facies conditions melting of quartz and feldspar assemblages is favored by during emplacement of and engulfment by the late the presence of excessive water and starts at a signifi- Cretaceous plutons. U/Pb zircon ages indicate the cantly lower temperature. In contrast, muscovite or emplacement of these plutons in the 100±2 Ma time biotite dehydration melting reactions occur at a much interval (Saleeby and Zeng 2005). higher temperature (e.g., Patin˜ o-Douce and Harris A geologic map of the area that was studied in detail 1998). In contrast to muscovite dehydration melting, within the Isabella pendant is shown in Fig. 1. The biotite dehydration melting is more complex because it is structure is characterized by a steeply SE-plunging iso- continuous over a wide range of temperatures. The clinal anticline with pelite units situated in core and temperature at which this reaction occurs depends on envelope positions of the fold. Metamorphic fabrics the composition of biotite (Mg/Fe ratio, Ti and F con- associated with the fold are L–S with the linear element centration) and the bulk Al content of source rocks (Le parallel to steeply plunging fold axes. Finite strain Breton and Thompson 1988; Vielzeuf and Montel 1994; studies on deformed pebble conglomerate in the Patin˜ o-Douce and Beard 1996; Stevens et al. 1997; quartzite unit indicate a stretch factor up to 1,000% Nabelek and Bartlett 2000). along the steep lineations. Homoaxial deformation in In this paper, we report the results of a detailed field satellite dikes from the Goat Ranch intrusion and leu- and geochemical study of a well-developed migmatite cosomes of the migmatitic pelite, as well as peak meta- zone in the Isabella pendant of the southern Sierra Ne- morphic textures, indicate that the isoclinal folding and vada batholith in California. This migmatite zone is of L–S fabric development occurred during pluton particular interest because it represents a single prograde emplacement. metamorphic sequence from greenshist facies metasedi- The upper pelite unit (J-pelite), which envelopes the ments to migmatites that lie in direct contact with the ca. large fold and is in contact with the Goat Ranch intru- 100 Ma Goat Ranch granodiorite pluton of the com- sion, has an apparent stratigraphic thickness in excess of posite batholith. Field relations
Load more

Recommended publications
  • The Segregation and Emplacement of Granitic Magmas
    Journal of the Geological society, London, Vol. 144, 1987, pp. 281-297, 13 figs. Printed in Northern Ireland The segregation and emplacement of granitic magmas S. M. WICKHAM Division of Geological and Planetary Sciences California Institute of Technology, Pasadena, California 91125 USA Abstract: The segregation of granitic magma from residual crystals at low melt-fraction is strongly dependent on the viscosity of the melt. Theoretical considerations imply that for the typical range of granitic meltviscosities (104Pa S to 10” Pa S) only verylimited separation will bepossible by a compaction mechanism over the typical duration of a crustal melting event (c. 106years). Small-scale segregations (millimetre to metre) of the type observed in migmatite terranes may be generated by compaction (possiblyassisted by -continuousdeformation), or byflow of melt into extensional fractures, but low melt-fraction liquids are unlikely to be extracted to form large (kilometre-size) granitic plutons because of the limited separation efficiency. At higher melt-fractions (>30%) the rapid decrease in strengthand effectiveviscosity during partial meltingallows other segregation processes tooperate. Calculations and experiments indicate that in granitic systems the effective viscosity of partially melted rocks,having a very narrow melt fraction range of 30-50% will fall rapidly to levels at which convective overturn of kilometre-thick zones can occur. Convective motion within anatectic regionsis capable of generating large (kilometre-size) homogeneous, highcrystal- fraction, crustally-derived magma bodies, which are orders of magnitude greater insize than low melt-fraction segregates. Before convective instability is reached, small (centimetre- to metre-sized) pods of granitic liquid may rise buoyantly through, and pond at the top of such partly molten zones; such a process is consistent with the observation that some granulites appear to be residue rocks, chemically depleted in a minimum melt component.
    [Show full text]
  • Full-Text PDF (Final Published Version)
    Pritchard, M. E., de Silva, S. L., Michelfelder, G., Zandt, G., McNutt, S. R., Gottsmann, J., West, M. E., Blundy, J., Christensen, D. H., Finnegan, N. J., Minaya, E., Sparks, R. S. J., Sunagua, M., Unsworth, M. J., Alvizuri, C., Comeau, M. J., del Potro, R., Díaz, D., Diez, M., ... Ward, K. M. (2018). Synthesis: PLUTONS: Investigating the relationship between pluton growth and volcanism in the Central Andes. Geosphere, 14(3), 954-982. https://doi.org/10.1130/GES01578.1 Publisher's PDF, also known as Version of record License (if available): CC BY-NC Link to published version (if available): 10.1130/GES01578.1 Link to publication record in Explore Bristol Research PDF-document This is the final published version of the article (version of record). It first appeared online via Geo Science World at https://doi.org/10.1130/GES01578.1 . Please refer to any applicable terms of use of the publisher. University of Bristol - Explore Bristol Research General rights This document is made available in accordance with publisher policies. Please cite only the published version using the reference above. Full terms of use are available: http://www.bristol.ac.uk/red/research-policy/pure/user-guides/ebr-terms/ Research Paper THEMED ISSUE: PLUTONS: Investigating the Relationship between Pluton Growth and Volcanism in the Central Andes GEOSPHERE Synthesis: PLUTONS: Investigating the relationship between pluton growth and volcanism in the Central Andes GEOSPHERE; v. 14, no. 3 M.E. Pritchard1,2, S.L. de Silva3, G. Michelfelder4, G. Zandt5, S.R. McNutt6, J. Gottsmann2, M.E. West7, J. Blundy2, D.H.
    [Show full text]
  • On Charnockites ⁎ B
    Available online at www.sciencedirect.com Gondwana Research 13 (2008) 30–44 www.elsevier.com/locate/gr GR Focus On charnockites ⁎ B. Ronald Frost , Carol D. Frost Department of Geology and Geophysics, University of Wyoming, Laramie, WY 82071, USA Received 4 June 2007; received in revised form 20 July 2007; accepted 24 July 2007 Available online 7 August 2007 Abstract Charnockitic rocks form extensive orthogneiss plutons in many granulite terranes and are less commonly found in unmetamorphosed plutons, which have formed in various tectonic regimes. Geochemically, clearly igneous charnockites cover nearly the whole range of granite chemistry, from magnesian to ferroan and from calcic to alkalic. Pyroxenes from unmetamorphosed charnockitic rocks have compositions ranging from magnesian to very iron-rich and record temperatures as high as 1000 °C. Oxygen fugacities for these plutons range from below FMQ to Δ log FMQN+2, values that cover nearly the whole range found in other granitic rocks. This range in bulk chemistry and intensive parameters is a reflection of the many mechanisms that produce charnockites. They may form in rifting environments, where they are ferroan, alkali-calcic to alkalic and metaluminous. Many of these ferroan charnockites are isotopically primitive, suggesting that they have been derived largely or entirely from differentiation or melting of tholeiitic melts. Charnockites are also found in deeply eroded arcs, where they are magnesian, calcic to calc-alkalic and metaluminous. Some charnockitic magmas may form by crustal melting or have incorporated a large component of crustal melt; these plutons tend to be weakly to moderately peraluminous and to have intermediate values of FeO/(FeO+MgO).
    [Show full text]
  • Shallow-Crustal Metamorphism During Late Cretaceous Anatexis in the Sevier Hinterland Plateau: Peak Temperature Conditions from the Grant Range, Eastern Nevada, U.S.A
    Shallow-crustal metamorphism during Late Cretaceous anatexis in the Sevier hinterland plateau: Peak temperature conditions from the Grant Range, eastern Nevada, U.S.A. Sean P. Long1*, Emmanuel Soignard2 1SCHOOL OF THE ENVIRONMENT, WASHINGTON STATE UNIVERSITY, PULLMAN, WASHINGTON 99164, USA 2LEROY EYRING CENTER FOR SOLID STATE SCIENCE, ARIZONA STATE UNIVERSITY, TEMPE, ARIZONA 85287, USA ABSTRACT Documenting spatio-temporal relationships between the thermal and deformation histories of orogenic systems can elucidate their evolu- tion. In the Sevier hinterland plateau in eastern Nevada, an episode of Late Cretaceous magmatism and metamorphism affected mid- and upper-crustal levels, concurrent with late-stage shortening in the Sevier thrust belt. Here, we present quantitative peak temperature data from the Grant Range, a site of localized, Late Cretaceous granitic magmatism and greenschist facies metamorphism. Twenty-two samples of Cambrian to Pennsylvanian metasedimentary and sedimentary rocks were analyzed, utilizing Raman spectroscopy on carbonaceous material, vitrinite reflectance, and Rock-Eval pyrolysis thermometry. A published reconstruction of Cenozoic extension indicates that the samples span pre-extensional depths of 2.5–9 km. Peak temperatures systematically increase with depth, from ~100 to 300 °C between 2.5 and 4.5 km, ~400 to 500 °C between 5 and 8 km, and ~550 °C at 9 km. The data define a metamorphic field gradient of ~60 °C/km, and are corroborated by quartz recrystallization microstructure and published conodont alteration indices. Metamorphism in the Grant Range is correlated with contemporary, upper-crustal metamorphism and magmatism documented farther east in Nevada, where metamorphic field gradients as high as ~50 °C/km are estimated.
    [Show full text]
  • The Archean Geology of Montana
    THE ARCHEAN GEOLOGY OF MONTANA David W. Mogk,1 Paul A. Mueller,2 and Darrell J. Henry3 1Department of Earth Sciences, Montana State University, Bozeman, Montana 2Department of Geological Sciences, University of Florida, Gainesville, Florida 3Department of Geology and Geophysics, Louisiana State University, Baton Rouge, Louisiana ABSTRACT in a subduction tectonic setting. Jackson (2005) char- acterized cratons as areas of thick, stable continental The Archean rocks in the northern Wyoming crust that have experienced little deformation over Province of Montana provide fundamental evidence long (Ga) periods of time. In the Wyoming Province, related to the evolution of the early Earth. This exten- the process of cratonization included the establishment sive record provides insight into some of the major, of a thick tectosphere (subcontinental mantle litho- unanswered questions of Earth history and Earth-sys- sphere). The thick, stable crust–lithosphere system tem processes: Crustal genesis—when and how did permitted deposition of mature, passive-margin-type the continental crust separate from the mantle? Crustal sediments immediately prior to and during a period of evolution—to what extent are Earth materials cycled tectonic quiescence from 3.1 to 2.9 Ga. These compo- from mantle to crust and back again? Continental sitionally mature sediments, together with subordinate growth—how do continents grow, vertically through mafi c rocks that could have been basaltic fl ows, char- magmatic accretion of plutons and volcanic rocks, acterize this period. A second major magmatic event laterally through tectonic accretion of crustal blocks generated the Beartooth–Bighorn magmatic zone assembled at continental margins, or both? Structural at ~2.9–2.8 Ga.
    [Show full text]
  • The Origin of Himalayan Anatexis and Inverted Metamorphism: Models and Constraints
    Journal of Asian Earth Sciences 17 (1999) 755±772 The origin of Himalayan anatexis and inverted metamorphism: Models and constraints T. Mark Harrison*, Marty Grove, Oscar M. Lovera, E.J. Catlos, Jessica D'Andrea Department of Earth and Space Sciences and Institute of Geophysics and Planetary Physics, University of California, Los Angeles, CA 90095-1567, USA Abstract The key to comprehending the tectonic evolution of the Himalaya is to understand the relationships between large-scale faulting, anatexis, and inverted metamorphism. The great number and variety of mechanisms that have been proposed to explain some or all of these features re¯ects the fact that fundamental constraints on such models have been slow in coming. Recent developments, most notably in geophysical imaging and geochronology, have been key to coalescing the results of varied Himalayan investigations into constraints with which to test proposed evolutionary models. These models fall into four general types: (1) the inverted metamorphic sequences within the footwall of the Himalayan thrust and adjacent hanging wall anatexis are spatially and temporally related by thrusting; (2) thrusting results from anatexis; (3) anatexis results from normal faulting; and (4) apparent inverted metamorphism in the footwall of the Himalayan thrust is produced by underplating of right-way-up metamorphic sequences. We review a number of models and ®nd that many are inconsistent with available constraints, most notably the recognition that the exposed crustal melts and inverted metamorphic sequences not temporally related. The generalization that appears to best explain the observed distribution of crustal melts and inverted metamorphic sequences is that, due to speci®c petrological and tectonic controls, episodic magmatism and out-of-sequence thrusting developed during continuous convergence juxtaposing allochthonous igneous and metamorphic rocks.
    [Show full text]
  • Geochemical Characterisation of Anatexite Within High Grade Migmatite Complex Terrain from Ogbomoso, Southwest of the Nigerian Precambrian Basement Complex
    American Scientific Research Journal for Engineering, Technology, and Sciences (ASRJETS) ISSN (Print) 2313-4410, ISSN (Online) 2313-4402 © Global Society of Scientific Research and Researchers http://asrjetsjournal.org/ Geochemical Characterisation of Anatexite within High Grade Migmatite Complex Terrain from Ogbomoso, Southwest of the Nigerian Precambrian Basement Complex Adegoke Olukayode Afolabia*, Rukayat Omobolanle Lawalb, Esther Olufunmilayo Ogunmiyidec, Kolade Adeosund a,b,c,dDepartment of Earth Sciences, Ladoke Akintola University of Technology, Ogbomoso, 210214, Nigeria aEmail: [email protected] bEmail: [email protected] cEmail: [email protected] dEmail: [email protected] Abstract Migmatite rocks are complex rocks largely due to the degree of partial melting and nature of parent rocks of this rock type. Partial melting or anatexis yield metatexite and diatexite components with variable mineralogical and chemical compositions. The nature of fractionation of elements during anatexis is not clearly understood. The migmatite quartzite gneiss complex of southwestern Nigeria exposed at Ogbomoso was studied in order to constrain the geochemical character of its metatexite and diatexite components. Field mapping revealed migmatite with stromatic, surreitic and dictyonitic structures represented the metatexite while parts of the migmatite with schollen structure and granitic component represent the diatexite. Several sections of representative samples were cut and examined for mineralogical compositions. Thin section
    [Show full text]
  • Granitoid Rocks Granitoids Common Features Anatexis? Evidence for Anaatexis Inclusions
    Granitoids “Granitoids” (sensu lato): loosely applies to a Granitoid Rocks wide range of felsic plutonic rocks This lecture focuses on non-continental arc Reading: intrusives Winter (2001) Chapter 18 Associated volcanics are common and have same origin, but are typically eroded away Common Features Anatexis? • Most large granitoid bodies occur in areas • Because the crust normally is solid, some thermal where the continental crust was thickened disturbance is required to form granitoids by orogeny • Most workers believe that the majority of • Formed by either continental arc granitoids are derived by crustal anatexis, but that subduction or collision of sialic masses. the mantle may also be involved in the process. • Many granites, however, may post-date the • The mantle contribution may range from being a thickening event by tens of millions of source of heat for crustal anatexis to being the years. source of material as well. Evidence for Inclusions Anaatexis Table 18-1. The Various Types of Enclaves Name Nature Margin Shape Features Backscattered electron image of a Xenolith piece of country sharp to angular contact metamorphic rocks gradual to ovoid texture and minerals zircon from the Strontian Granite, Xenocryst isolated foreignsharp angular corroded Scotland. The grain has a rounded, crystal reaction rim Surmicaceous residue of melting sharp, lenticular metamorphic texture un-zoned core (dark) that is an Enclave (restite) biotite rim micas, Al-rich minerals inherited high-temperature non- Schlieren disrupted enclave gradual oblate coplanar orientation Felsic Micro- disrupted sharp to ovoid fine-granied melted crystal from the pre-granite granular Enclave fine-grained margin gradual igneous texture source.
    [Show full text]
  • Geochemical Characteristics of Crustal Anatexis During the Formation of Migmatite at the Southern Sierra Nevada, California
    Contrib Mineral Petrol (2005) DOI 10.1007/s00410-005-0010-2 ORIGINAL PAPER Lingsen Zeng Æ Jason B. Saleeby Æ Mihai Ducea Geochemical characteristics of crustal anatexis during the formation of migmatite at the Southern Sierra Nevada, California Received: 6 October 2003 / Accepted: 10 March 2005 Ó Springer-Verlag 2005 Abstract We provide data on the geochemical and iso- tively high Rb, Pb, Ba, and K2O contents, Rb/Sr ratios topic consequences of nonmodal partial melting of a (0.15<Rb/Sr<1.0), and initial eNd values . Group B thick Jurassic pelite unit at mid-crustal levels that pro- leucosomes have relatively low Rb, Pb, Ba, and K2O duced a migmatite complex in conjunction with the contents, Rb/Sr ratios (<0.15), and initial eNd values. intrusion of part of the southern Sierra Nevada batho- The low Rb concentrations and Rb/Sr ratios of the lith at ca. 100 Ma. Field relations suggest that this pelitic group B leucosomes together suggest that partial melting migmatite formed and then abruptly solidified prior to was dominated by water-saturated or H2O-fluxed melt- substantial mobilization and escape of its melt products. ing of quartz + feldspar assemblage with minor Hence, this area yields insights into potential mid-crustal involvement of muscovite. Breakdown of quartz and level contributions of crustal components into Cordil- plagioclase with minor contributions from muscovite leran-type batholiths. Major and trace-element analyses resulted in low Rb/Sr ratios characterizing both group A in addition to field and petrographic data demonstrate and group B leucosomes. In contrast, group A leuco- that leucosomes are products of partial melting of the somes have greater contributions from K-feldspar, pelitic protolith host.
    [Show full text]
  • The Role of Partial Melting and Extensional Strain Rates in the Development of Metamorphic Core Complexes
    Tectonophysics 477 (2009) 135–144 Contents lists available at ScienceDirect Tectonophysics journal homepage: www.elsevier.com/locate/tecto The role of partial melting and extensional strain rates in the development of metamorphic core complexes P.F. Rey a,⁎, C. Teyssier b, D.L. Whitney b a Earthbyte Research Group, School of Geosciences, University of Sydney, NSW2006 Sydney, Australia b Department of Geology and Geophysics, University of Minnesota, Minneapolis, Minnesota 55455, USA article info abstract Article history: Orogenic collapse involves extension and thinning of thick and hot (partially molten) crust, leading to the Received 11 September 2008 formation of metamorphic core complexes (MCC) that are commonly cored by migmatite domes. Two- Accepted 12 March 2009 dimensional thermo-mechanical Ellipsis models evaluate the parameters that likely control the formation and Available online 20 March 2009 evolution of MCC: the nature and geometry of the heterogeneity that localizes MCC, the presence/absence of a partially molten layer in the lower crust, and the rate of extension. When the localizing heterogeneity is a Keywords: normal fault in the upper crust, the migmatite core remains in the footwall of the fault, resulting in an Continental extension Migmatite asymmetric MCC; if the localizing heterogeneity is point like region within the upper crust, the MCC remains Metamorphic core complex symmetric throughout its development. Therefore, asymmetrically located migmatite domes likely reflect the Gneiss dome dip of the original normal fault system that generated the MCC. Modeling of a severe viscosity drop owing to the Partial melting presence of a partially molten layer, compared to a crust with no melt, demonstrates that the presence of melt Modeling slightly enhances upward advection of material and heat.
    [Show full text]
  • Dictionary of Geology and Mineralogy
    McGraw-Hill Dictionary of Geology and Mineralogy Second Edition McGraw-Hill New York Chicago San Francisco Lisbon London Madrid Mexico City Milan New Delhi San Juan Seoul Singapore Sydney Toronto All text in the dictionary was published previously in the McGRAW-HILL DICTIONARY OF SCIENTIFIC AND TECHNICAL TERMS, Sixth Edition, copyright ᭧ 2003 by The McGraw-Hill Companies, Inc. All rights reserved. McGRAW-HILL DICTIONARY OF GEOLOGY AND MINERALOGY, Second Edi- tion, copyright ᭧ 2003 by The McGraw-Hill Companies, Inc. All rights reserved. Printed in the United States of America. Except as permitted under the United States Copyright Act of 1976, no part of this publication may be reproduced or distributed in any form or by any means, or stored in a database or retrieval system, without the prior written permission of the publisher. 1234567890 DOC/DOC 09876543 ISBN 0-07-141044-9 This book is printed on recycled, acid-free paper containing a mini- mum of 50% recycled, de-inked fiber. This book was set in Helvetica Bold and Novarese Book by the Clarinda Company, Clarinda, Iowa. It was printed and bound by RR Donnelley, The Lakeside Press. McGraw-Hill books are available at special quantity discounts to use as premi- ums and sales promotions, or for use in corporate training programs. For more information, please write to the Director of Special Sales, McGraw-Hill, Professional Publishing, Two Penn Plaza, New York, NY 10121-2298. Or contact your local bookstore. Library of Congress Cataloging-in-Publication Data McGraw-Hill dictionary of geology and mineralogy — 2nd. ed. p. cm. “All text in this dictionary was published previously in the McGraw-Hill dictionary of scientific and technical terms, sixth edition, —T.p.
    [Show full text]
  • Granitoid Magmas Preserved As Melt Inclusions in High-Grade Metamorphic Rocksk
    American Mineralogist, Volume 101, pages 1543–1559, 2016 SPECIAL COLLECTION: PERSPECTIVES ON ORIGINS AND EVOLUTION OF CRUSTAL MAGMAS Granitoid magmas preserved as melt inclusions in high-grade metamorphic rocksk OMAR BARTOLI1,*, ANTONIO ACOSTA-VIGIL1,2, SILVIO FERRERO3,4, AND BERNARDO CESARE1 1Dipartimento di Geoscienze, Università di Padova, Via Gradenigo 6, 35131 Padova, Italy 2Instituto Andaluz de Ciencias de la Tierra, Consejo Superior de Investigaciones Científicas and Universidad de Granada, Armilla, Granada, Spain 3Institut für Geowissenschaften, Universität Potsdam, Karl-Liebknecht-Strasse 24/25, D-14476 Golm, Germany 4Museum für Naturkunde (MfN), Leibniz-Institut für Evolutions- und Biodiversitätsforschung, 10115 Berlin, Germany ABSTRACT This review presents a compositional database of primary anatectic granitoid magmas, entirely based on melt inclusions (MI) in high-grade metamorphic rocks. Although MI are well known to igneous petrologists and have been extensively studied in intrusive and extrusive rocks, MI in crustal rocks that have undergone anatexis (migmatites and granulites) are a novel subject of research. They are generally trapped along the heating path by peritectic phases produced by incongruent melting reactions. Primary MI in high-grade metamorphic rocks are small, commonly 5–10 μm in diameter, and their most com- mon mineral host is peritectic garnet. In most cases inclusions have crystallized into a cryptocrystalline aggregate and contain a granitoid phase assemblage (nanogranitoid inclusions) with quartz, K-feldspar,
    [Show full text]