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Suprasubduction-zone peridotite in the northern USA Appalachians: evidence from mineral composition

Published online by Cambridge University Press:  05 July 2018

R. A. Coish  and
P. Gardner
R. A. Coish*
Affiliation:
Geology Department, Bicentennial Hall, Middlebury College, Middlebury, Vermont 05753, USA
P. Gardner
Affiliation:
Geology Department, Bicentennial Hall, Middlebury College, Middlebury, Vermont 05753, USA
*
*E-mail: [email protected]
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Abstract

Mineral compositions of small peridotite bodies in an Ordovician collision zone of the Vermont Appalachians provide important clues to their tectonic environment of origin. The bodies have been deformed and partially serpentinized under greenschist- to lower amphibolite-facies conditions during the Ordovician and Devonian. Before serpentinization, the peridotite bodies were dunite as shown by their mineral assemblage and by their high MgO, and low Ti and Al whole-rock contents. Despite deformation and metamorphism, remnant olivine and spinel grains occur; their compositions are taken to represent conditions prior to regional metamorphic events. High Mg/(Mg+Fe) in olivine and very high Cr/(Cr+Al) in spinel indicate that the peridotites formed as highly-depleted mantle residues. The compositions are similar to those in harzburgite and dunite from some ophiolites and from fore-arc regions of subduction zones. Accordingly, the southern Vermont peridotites probably formed in a forearc, supra-subduction zone during the Early Palaeozoic. They were subsequently emplaced by obduction of the upper plate of an east-facing subduction complex.

Keywords

peridotitesubduction zoneAppalachiansVermontUSA
Type
Research Article
Information
Mineralogical Magazine , Volume 68 , Issue 4 , August 2004 , pp. 699 - 708
Copyright
Copyright © The Mineralogical Society of Great Britain and Ireland 2004

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References

Arai, S. (1994a) Compositional variation of olivinechromian spinel in Mg-rich magmas as a guide to their residual spinel peridotites. Journal of Volcanology and Geothermal Research, 59, 279293.CrossRefGoogle Scholar
Arai, S. (1994b) Characterization of spinel peridotites by olivine-spinel compositional relationships; review and interpretation. Chemical Geology, 113, 191204.CrossRefGoogle Scholar
Barnes, S.J. and Roeder, P.L. (2001) The range of spinel compositions in terrestrial mafic and ultramafic rocks. Journal of Petrology, 42, 22792302.CrossRefGoogle Scholar
Bédard, J.H., Schroetter, J.M., Pagé, P., Tremblay, A. and Bécu, V. (2003) Pre-obduction structural and magmatic evolution of the Thetford Mines ophiolite complex: a record of fore-arc extension and seafloor spreading. Geological Society of America, Abstracts with Program, 35, 3, p. 59.Google Scholar
Brown, G.C. and Mussett, A.E. (1993) The Inaccessible Earth: an Integrated View to its Structure and Composition, xi. Chapman & Hall, London, New York, 276 pp.CrossRefGoogle Scholar
Canil, D. (2002) Vanadium in peridotites, mantle redox and tectonic environments: Archean to present. Earthand Planetary Science Letters, 195, 7590.CrossRefGoogle Scholar
Coish, R.A. (1997) Rift and ocean floor volcanism from the Late Paleozoic and early Paleozoic of the Vermont Appalachians. Pp. 129–45 in: The Nature of Magmatism in the Appalachian Orogen (Sinha, A.K., Whalen, J.B. and Hogan, J.P., editors). Memoir 191, Geological Society of America, Boulder, Colorado.Google Scholar
Coish, R.A. and Gardner, P. (2002) Geochemistry and tectonic implications of serpentinized ultramafic rocks in Vermont. Geological Society of America, Abstracts with Programs, 34, p. 361.Google Scholar
Coleman, R.G. (1984) The diversity of ophiolites. Geologie en Mijnbouw, 63, 141150.Google Scholar
Deregibus, K. (1981) Petrology of the Ultramafic Body near Ludlow, Vermont. BA thesis, Middlebury College, Vermont, USA, 42 pp.Google Scholar
Dewey, J.F. and Bird, J.M. (1971) Origin and emplacement of the ophiolite suite: Appalachian ophiolites in Newfoundland. Journal of Geophysical Research, 76, 31793206.CrossRefGoogle Scholar
Dick, H.J.B. and Bullen, T. (1984) Chromian spinel as a petrogenetic indicator in abyssal and alpine-type peridotites and spatially associated lavas. Contributions to Mineralogy and Petrology, 86, 5476.CrossRefGoogle Scholar
Doll, C.G., Cady, W.M., Thompson, J.B. and Billings, M.P. Jr. (1961) Centennial geologic map of Vermont. Vermont Geological Survey, scale 1:250, 000, 1 sheet.Google Scholar
Doolan, B.L., Gale, M.H., Gale, P.N. and Hoar, R.S. (1982) Geology of the Quebec Reentrant: possible constraints from early rifts and the Vermont-Quebec serpentine belt. Pp. 87115 in: Major Structural Zones and Faults of the Northern Appalachians (St. Julien, P. and Na3, editors). Special Paper 7, Geological Association of Canada.Google Scholar
Hellebrand, E., Snow, J.E. and Mühe, R. (2002) Mantle melting beneath Gakkel Ridge (Arctic Ocean): Abyssal peridotite spinel compositions. Chemical Geology, 182, 227235.CrossRefGoogle Scholar
Hoffman, M.A. and Walker, D. (1978) Textural and chemical variations of olivine and chrome spinel in the East Dover ultramafic bodies, south-central Vermont. Geological Society of America Bulletin, 89, 699710.2.0.CO;2>CrossRefGoogle Scholar
Huot, F., Hébert, R. and Turcotte, B. (2002) A multistage magmatic history for the genesis of the Orford Ophiolite (Quebec, Canada); a study of the Mont Chagnon Massif. Canadian Journal of Earth Sciences, 39, 12011217.CrossRefGoogle Scholar
Kametesky, V.S., Crawford, A.J. and Meffre, S. (2001) Factors controlling chemistry of magmatic spinel: an empirical study of associated olivine, Cr-spinel and melt inclusions from primitive rocks. Journal of Petrology, 42, 655671.CrossRefGoogle Scholar
Karabinos, P. (1998) Tectonic and stratigraphic development of the Connecticut Valley Trough in the New England Appalachians. Geological Society of America, Abstracts with Programs, 30, 7, p. 191.Google Scholar
Karabinos, P. and Hepburn, J.C. (2001) Geochronology and geochemistry of the Shelburne Falls arc: the Taconic Orogeny in western New England. Pp. H120 in: Guidebook to Geological Field Trips in New England (West, D.P. Jr. and Bailey, R.H., editors). Geological Society of America, Boulder, Colorado.Google Scholar
Karabinos, P., Samson, S.D., Hepburn, J.C. and Stoll, H.M. (1998) Taconian orogeny in the New England Appalachians; collision between Laurentia and the Shelburne Falls Arc. Geology, 26, 215218.2.3.CO;2>CrossRefGoogle Scholar
Kim, J. and Jacobi, R.D. (1996) Geochemistry and tectonic implications of Hawley Formation metaigneous units: northwestern Massachusetts. American Journal of Science, 296, 11261174.CrossRefGoogle Scholar
Kim, J. and Jacobi, R.D. (2002) Boninites: Characteristics and tectonic constraints, northeastern Appalachians. Physics and Chemistry of the Earth, 27, 109147.CrossRefGoogle Scholar
Kim, J., Coish, R., Evans, M. and Dick, G. (2003) Supra-subduction zone extensional magmatism in Vermont and adjacent Quebec; implications for early Paleozoic Appalachian tectonics. Geological Society of America Bulletin, 115, 15521569.CrossRefGoogle Scholar
Koga, K., Keleman, P.B. and Shimizu, N. (2001) Petrogenesis of the crust-mantle transition zone and the origin of lower crustal wehrlite in the Oman ophiolite. Geochemistry Geophysics Geosystems, 2, Paper number 2000GC000132.CrossRefGoogle Scholar
Kubo, K. (2002) Dunite formation processes in highly depleted peridotite: case study of the Iwanaidake peridotite, Hokkaido, Japan. Journal of Petrology, 43, 423448.CrossRefGoogle Scholar
Kusky, T.M., Li, J.-H. and Tucker, R.D. (2001) The Archean Dongwanzi ophiolite complex, north China craton: 2.505-billion-year-old oceanic crust and mantle. Science, 292, 11421145.CrossRefGoogle ScholarPubMed
Metzger, E.P., Miller, R.B. and Harper, G.D. (2002) Geochemistry and tectonic setting of the ophiolitic Ingalls Complex, North Cascades, Washington: Implications for correlations of Jurassic Cordilleran ophiolites. Journal of Geology, 110, 543560.CrossRefGoogle Scholar
Moores, E.M. (1982) Origin and emplacement of ophiolites. Reviews in Geophysical and Space Physics, 20, 735760.CrossRefGoogle Scholar
Ohara, Y., Stern, R.J., Ishii, T., Yurimoto, H. and Yamazaki, T. (2002) Peridotites from the Mariana Trough; first look at the mantle beneath an active back-arc basin. Contributions to Mineralogy and Petrology, 143, 118.CrossRefGoogle Scholar
Olive, V., Hébert, R. and Loubet, M. (1997) Isotopic and trace element constraints on the genesis of a boninitic sequence in the Thetford Mines ophiolitic complex, Québec, Canada. Canadian Journal of EarthSciences, 34, 12581271.CrossRefGoogle Scholar
Oshin, I.O. and Crocket, J.H. (1986) The geochemistry and petrogenesis of ophiolitic volcanic rocks from Lac del’Est Thetford Mines Complex, Quebec, Canada. Canadian Journal of EarthSciences, 23, 202213.CrossRefGoogle Scholar
Parkinson, I.J. and Pearce, J.A. (1998) Peridotites from the Izu-Bonin-Mariana forearc (ODP Leg 125); evidence for mantle melting and melt-mantle interaction in a supra-subduction zone setting. Journal of Petrology, 39, 15771618.CrossRefGoogle Scholar
Pearce, J.A., Barker, P.F., Edwards, S.J., Parkinson, I.J. and Leat, P.T. (2000) Geochemistry and tectonic significance of peridotites from the South Sandwich arc-basin system, South Atlantic. Contributions to Mineralogy and Petrology, 139, 3653.CrossRefGoogle Scholar
Pinet, N. and Tremblay, A. (1995) Is the Taconian orogeny of southern Quebec the result of an Omantype obduction? Geology, 23, 121124.2.3.CO;2>CrossRefGoogle Scholar
Quick, J.E. (1981) The origin and significance of large dunite bodies in the Trinity peridotite, Northern California. Contributions to Mineralogy and Petrology, 77, 185194.Google Scholar
Rankin, D.W. (1994) Continental margin of the eastern United States: past and present. Pp. 129218 in: Phanerozoic Evolution of North American Continent-Ocean Transitions (Speed, R.C., editor). DNAG Continent-Ocean Transect Volume, Geological Society of America, Boulder, Colorado.Google Scholar
Ratcliffe, N.M., Hames, W.E. and Stanley, R.S. (1998) Interpretation of ages of arc magmatism, metamorphism and collisional tectonics in the Taconian Orogen of western New England. American Journal of Science, 298, 791797.CrossRefGoogle Scholar
Robertson, A.H.F. (2002) Overview of the genesis and emplacement of Mesozoic ophiolites in the eastern Mediterranean Tethyan region. Lithos, 65, 167.CrossRefGoogle Scholar
Stanley, R.S. and Ratcliffe, N.M. (1985) Tectonic synthesis of the Taconian orogeny in western New England. Geological Society of America Bulletin, 96, 12271250.2.0.CO;2>CrossRefGoogle Scholar
Stanley, R.S., Roy, D.L., Hatch, N.L. and Knapp, D.A. (1984) Evidence for tectonic emplacement of ultramafic and associated rocks in the Pre-Silurian belt of western New England. American Journal of Science, 284, 559595.CrossRefGoogle Scholar
Suhr, G., Seck, H.A., Shimizu, N., Günther, D. and Jenner, G. (1998) Infiltration of refractory melts into the lowermost crust: evidence from dunite- and gabbro-hosted clinopyroxenes in the Bay of Islands ophiolite. Contributions to Mineralogy and Petrology, 131, 136154.CrossRefGoogle Scholar
Waldron, J.W.F. and van Staal, C.R. (2001) Taconian Orogeny and the accretion of the Dashwoods Block; a peri-Laurentian microcontinent in the Iapetus Ocean. Geology, 29, 811–81.2.0.CO;2>CrossRefGoogle Scholar