The heterogeneous mantle massif in south Tibetan ophiolites and its implication for the tectonic evolution of Neo-Tethys

Abstract

Ophiolitic mantle peridotites show large variations in their geochemical compositions, which provide important information for the histories of mantle melting, melt metasomatism and prior melt depletion in the context of tectonic evolution of ancient oceans. Here we report new petrological and geochemical data for mantle peridotites from the Zhagabu ophiolite in south Tibet, which could represent fossil upper mantle of the Mesozoic Neo-Tethys oceanic lithosphere. The Zhagabu mantle peridotites, including spinel lherzolites and spinel harzburgites, have highly heterogeneous geochemical compositions, with whole-rock Al2O3 of 0.3–2.0 wt% and CaO of 0.3–2.2 wt%, and spinel Cr# [Cr/(Cr + Al)] of 0.21–0.74 and Mg# [Mg/(Mg + Fe2+)] of 0.44–0.74. The clinopyroxenes from the studied samples show extremely depletion in light rare earth element compositions, some of which however are elevated by post-melting melt-rock interactions. Spinel and clinopyroxene compositions collectively suggest that the Zhagabu mantle peridotites have experienced ~9–20% of fractional melting from a depleted mid-ocean ridge basalt mantle source. Trace element modeling of clinopyroxenes further indicates that some of the studied samples follow the refertilization-hydrous melting trends with variable fluid fluxes. Therefore, the heterogeneous compositions of the Zhagabu mantle peridotites are not comparable to those of either abyssal peridotites or forearc peridotites, but most probably record a dynamic transition from the anhydrous condition beneath the Neo-Tethyan mid-ocean ridge to the hydrous condition above the subducted slab. Considering that a forearc spreading is in contradiction with the low magma budget of Yarlung Zangbo ophiolites, the Neo-Tethyan subduction re-initiation was suggested to be achieved along oceanic detachment faults at ultraslow-spreading ridges. The Zhagabu mantle peridotites represent the very heterogeneous mantle massif in south Tibetan ophiolites, and provide an excellent window to investigate the complex mantle dynamics and tectonic evolution of the Neo-Tethys Ocean.