V43A-3105
Southward Ejection of Subcontinental Lithosphere and large-scale Asthenospheric Enrichment beneath central Chile resulting from Flat Subduction
Thursday, 17 December 2015
Poster Hall (Moscone South)
Kaj Hoernle1, Guillaume Jacques1, Bruce F Schaefer2, Folkmar Hauff1, James Gill3, Paul M Holm4, Ilya N Bindeman5, Andres Folguera6, Luis Lara7 and Victor A Ramos6, (1)GEOMAR Helmholtz Centre for Ocean Research Kiel, Kiel, Germany, (2)Macquarie University, Sydney, Australia, (3)University of California Santa Cruz, Santa Cruz, CA, United States, (4)University of Copenhagen, Copenhagen, Denmark, (5)University of Oregon, Department of Geological Sciences, Eugene, OR, United States, (6)Instituto de Estudios Andinos, Universidad de Buenos Aires, Argentina, (7)SERNAGEOMIN National Geology and Mining Service, Santiago, Chile
Abstract:
Flat subduction is a common process in subduction zones, causing crustal shortening and thickening and possibly subduction erosion. These processes can lead to the contamination of asthenospheric melts either by lithospheric assimilation (e.g. MASH) or by subduction erosion of lithosphere into the asthenospheric source. We present new major and trace element and Sr-Nd-Pb-Hf-O-Os isotope data for a transect of Quaternary volcanic rocks across the Northern Southern Volcanic Front (NSVZ) of Chile at ~33.5°S, just south of the area of flat subduction, extending from the volcanic front (VF) to the rear arc (RA). The newly discovered calc-alkaline to alkaline RA rocks are more mafic (MgO~4-9wt.%) than the VF rocks (MgO~2.0-4.5wt.%). Both groups have overlapping Sr-Nd-Hf isotopic compositions that are more enriched than lavas from further south in the SVZ with two RA trachybasalts displaying extreme 87Sr/86Sr (0.710), eNd (-6) and eHf (-9). The RA samples, however, have less radiogenic Pb isotopic compositions with the two extreme RA trachybasalt samples having the least radiogenic Pb. The 207Pb/204Pb vs. Nd/Pb, Ce/Pb and Nb/U form good inverse linear correlations extending from subducted sediments to a mantle-like component. Mesozoic/Paleozoic crust and Grenvillian Argentinian lower crust do not fall on or along an extension of these arrays. The ol, plag and groundmassd18O (normalized to melt) of samples covering the full range in Sr-Nd-Pb-Hf isotopic composition lie within the mantle range (5.5-5.9). High Os abundances (~330ppt) in radiogenic Os (187Os/188Os=0.18) samples are not consistent with derivation from a mantle plume or continental crust. eNd and eHf increase to the south along the VF, e.g. eHf ranges from -9 to +10, forming an excellent linear correlation (r2=0.99), indicating that the enriched component is present in the source for >1000km to at least ~43°S. We propose that flattening of the Pampean slab 1) triggered subduction erosion of enriched Proterozoic subcontinental lithospheric mantle and 2) squeezed the eroded lithosphere radially away from the region of flat subduction. Therefore, flat subduction could be a major mechanism for transferring continental lithosphere into the upper mantle asthenosphere, and for distributing this enriched material laterally over 1000s of kilometers.
