Open Access
Evidence for a Moist to Wet Source Transition Throughout the Oman‐UAE Ophiolite, and Implications for the Geodynamic History
Author(s) -
Graaff S. J.,
Goodenough K. M.,
Klaver M.,
Lissenberg C. J.,
Jansen M. N.,
Millar I.,
Davies G. R.
Publication year - 2019
Publication title -
geochemistry, geophysics, geosystems
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.928
H-Index - 136
ISSN - 1525-2027
DOI - 10.1029/2018gc007923
Subject(s) - ophiolite , geology , geochemistry , amphibole , gabbro , oceanic crust , lithosphere , peridotite , mantle (geology) , basalt , subduction , tectonics , paleontology , quartz
Abstract The Oman‐United Arab Emirates (UAE) ophiolite represents the largest and best‐preserved fragment of obducted oceanic lithosphere in the world. However, debate continues regarding its geodynamic history. This debate is in part a consequence of the lateral variability in the later stage magmatic units, with arc signatures considered to be well developed in the north of the ophiolite but less so in the south. In this study, we investigate later stage intrusions in the central and southern part of the ophiolite. These intrusions vary from wehrlite to gabbro and tonalite and crosscut all levels of the main ophiolite sequence from the mantle peridotites up to the sheeted dike complex. They are characterized by the presence of magmatic amphibole, low TiO 2 (<1 wt%), document an enrichment in Th, Sr, and Ba, depletion of Y and Dy, and decreasing Dy/Yb and Dy/Dy* with increased fractionation. These data record hydrous fractionation with a significant role for amphibole, which is comparable to many arc‐type magmas. The relative Nb and light rare earth element ((La/Yb)n chon < 1) depletion and coupled Nd and Hf isotope variations indicate the same (but depleted) Indian mid‐ocean ridge basalts‐type mantle source as the main ophiolite sequence. More radiogenic Pb isotope compositions of plagioclase imply the addition of a fluid component likely derived from sediments or altered oceanic crust. These intrusions occur across larger areas than previously reported, implying the entire ophiolite formed in a setting characterized by arc‐type magmas, such as a suprasubduction zone setting.