Refining the Early History of the Mojave-Yavapai Boundary Zone: Rifting versus Arc Accretion as Mechanisms for Paleoproterozoic Crustal Growth in Southwestern Laurentia

Three outstanding questions regarding Paleoproterozoic crustal growth and assembly in southwestern Laurentia are (1) the mechanisms of crustal growth (back-arc rifting and associated juvenile magmatism vs. accretion of juvenile arcs), (2) the nature and significance of pre-Yavapai orogeny (>1.70...

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Bibliographic Details
Published in:The Journal of geology 2015-01, Vol.123 (1), p.21-37
Main Author: Duebendorfer, Ernest M.
Format: Article
Language:English
Subjects:
Basins
Biotite
Canyons
Deformation
Geology
Gneiss
Granite
Isotopes
Magmatism
Orogeny
Protoliths
Provinces
Rocks
Schist
Sediments
Tectonics
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Summary:Three outstanding questions regarding Paleoproterozoic crustal growth and assembly in southwestern Laurentia are (1) the mechanisms of crustal growth (back-arc rifting and associated juvenile magmatism vs. accretion of juvenile arcs), (2) the nature and significance of pre-Yavapai orogeny (>1.70 Ga) deformation, and (3) how the isotopically mixed boundary zone between the Mojave and Yavapai Paleoproterozoic crustal provinces formed. Supracrustal successions associated with the Mojave-Yavapai boundary zone in northwestern Arizona are dominated by >1730 Ma bimodal metavolcanic sequences and compositionally siliciclastic metasedimentary rocks, with minor ultramafic rocks, chert, and carbonate. This lithologic assemblage requires juvenile mafic volcanism in a basin that also received abundant quartz-rich (i.e., continental) detritus. A pre-D1 (first deformational event), back-arc rift setting for northwestern Arizona best explains the observed supracrustal assemblage. Plutonic rocks that intrude the supracrustal rocks are generally 5–15 m.yr. younger and span the entire compositional range of granitoids; i.e., they are not plutonic equivalents of the metavolcanic rocks. In the model presented here, supracrustal rocks were deposited in a back-arc basin above an east-dipping subduction zone undergoing slab rollback. Subsequent shallowing of the subducting slab resulted in (1) eastward migration of 1.76–1.74 Ga arc magmatism in eastern California to 1.73–1.71 Ga arc magmatism within the former back-arc basin in northwestern Arizona, (2) consequent closure of the back-arc basin, (3) thrusting of Yavapai province rocks over the basin (D1), resulting in (4) burial of supracrustal rocks to >20 km, and ultimately, (5) gravitational collapse of the orogen. These events predated the 1.70–1.68 Ga Yavapai orogeny and occurred within a time interval of 5–20 m.yr. Similar time intervals for tectonic switching have been documented from the Lachlan orogen of eastern Australia. Rifting and associated magmatism and arc accretion are both viable—and not mutually exclusive—mechanisms for crustal growth.
ISSN:0022-1376
1537-5269
DOI:10.1086/678950