Contents lists available at ScienceDirect Ore Geology Reviews journal homepage: www.elsevier.com/locate/oregeorev Composite origin of magnetite deposits hosted in Oman peridotites: Evidence for iron mobility during serpentinization Mohamed Zaki Khedr a, ⁎ , Shoji Arai b a Department of Geology, Faculty of Science, Kafrelsheikh University, 33516, Egypt b Department of Earth Sciences, Kanazawa University, Ishikawa 920-1192, Japan ARTICLE INFO Keywords: Magnetite deposits Hydrothermal origin Nonconformity Serpentinites Iron mobility Oman ophiolite ABSTRACT We describe mineralogy of magnetite deposits concentrated within a nonconformity surface between Aniba serpentinites and overlying limestones in the Southern Oman ophiolite and discuss their origin to understand iron mobility during serpentinization, with special reference to factors controlling the magnetite-orebody sizes. The Aniba magnetite deposits occur in several forms such as fibrous crystals, oval or rounded grains, strings and cluster shapes, in fine-grained iron-rich chlorite and calcite matrices. The chromian spinel (Cr# = 0.38–0.56) within the magnetite deposits is similar in texture, mode of occurrence and chemical composition to that in the underlying serpentinized harzburgites (chromian spinel Cr# = 0.37–0.50), and plots in the space of abyssal peridotites. The mineral chemistry of chromian spinel, olivine and clinopyroxene (Cpx) suggested that the Aniba harzburgites are refractory residue after high-degree (15–25%) partial melting and are similar to abyssal harzburgites from a normal ridge segment. This is confirmed by a Cpx trace-element character with high de- pletion in light rare earth elements (LREE), Ta and Zr relative to heavy REE. The iron of our magnetite deposits was possibly derived from two sources: one is an essentially internal source of iron from the breakdown of Fe- rich serpentines after olivine during low-T serpentinization (< 400 °C) and the external source of iron from hydrous fluids. The essential origin of our magnetite deposits is hydrothermal one due to the mobility and leaching of iron from serpentinites and the in-situ selective precipitation of iron within the nonconformity surface. This process was feasible because the nonconformity zone was a weathering surface, a channel for both hydrothermal-fluid flow providing high fluid/rock ratios that enhance iron mobilization in serpentinites and leach iron, besides chromian spinel grains, from the host ultramafic rocks. Chromian spinel grains (up to 10 vol %) in the magnetite deposits were of a residual detrital origin from the underlying serpentinized peridotites on weathering, and acted as a nucleus for magnetite precipitation. The morphology and colloform shape of some magnetite grains reflect their supergene origin. Factors controlling the size of the magnetite deposits include the compositions of the underlying serpentinized harzburgites as a main source of iron, high fluid/rock ratios and high iron mobility within fluid conduits such as a nonconformity surface, abundance of chromian spinel grains as a nucleus for magnetite concentration, low silica activity, pressure of water and oxygen fugacity. 1. Introduction Magnetite orebodies generally occur in the form of massive de- posits, semi-massive, disseminated, pod-like, vein-like and string-like bodies, ranging from a few centimeters to hundreds of meters in sizes (Diella et al., 1994; Rossetti et al., 2009). Several studies have discussed the origin of magnetite orebodies: including magmatic (Volkert et al., 2005; Dare et al., 2014; Khedr and Arai, 2016b), metamorphic (Zucchetti et al., 1988; Diella et al., 1994; Giusta et al., 2011; Khedr and Arai, 2013) and hydrothermal origins of magnetite in Bou Azzer (Morocco) and Iran ophiolites (Puffer, 2001; Puffer and Gorring, 2005; Gahlan et al., 2006; Kalczynski and Gates, 2014; Dare et al., 2014; Klein et al., 2014; Hodel et al., 2017; Eslami et al., 2018). Magmatic mag- netites are characterized by tabular, columnar or dike-like shaped un- deformed orebodies. These deposits, such as the columnar magnetites found in the El Laco volcano in the Chilean Andes, are very poor in Cr (< 10 ppm) and relatively rich in V (1000–2000 ppm) (Nyström and Henríquez, 1994). Magnetite deposits of the metamorphic origin from the Western Alps of Italy are famous and interpreted as a product of the transformation from chromite proto-ores during the Alpine meta- morphism, and occur as bands around relic chromian spinel (Zucchetti et al., 1988; Diella et al., 1994; Giusta et al., 2011). https://doi.org/10.1016/j.oregeorev.2018.07.003 Received 15 December 2017; Received in revised form 30 June 2018; Accepted 9 July 2018 ⁎ Corresponding author. E-mail address: mohamed.khader1@sci.kfs.edu.eg (M.Z. Khedr). Ore Geology Reviews 101 (2018) 180–198 Available online 10 July 2018 0169-1368/ © 2018 Elsevier B.V. All rights reserved. T