The origin of Earth’s volatiles has been attributed to a late
addition of meteoritic material after core-mantle differentiation. The nature
and consequences of this 'late veneer' are debated, but may be
traced by isotopes of the highly siderophile, or iron-loving, and volatile
element selenium. Here we present high-precision selenium isotope data for
mantle peridotites, from double spike and hydride generation multi-collector
inductively coupled plasma mass spectrometry. These data indicate that the
selenium isotopic composition of peridotites is unaffected by petrological
processes, such as melt depletion and melt-rock reaction, and thus a narrow range
is preserved that is representative of the silicate Earth. We show that selenium
isotopes record a signature of late accretion after core formation and that this
signature overlaps only with that of the CI-type carbonaceous chondrites. We
conclude that these isotopic constraints indicate the late veneer originated
from the outer Solar System and was of lower mass than previously estimated.
Thus, we suggest a late and highly concentrated delivery of volatiles enabled
Earth to become habitable.
Mantle xenoliths in Pliocene alkali basalts of the eastern Betics (SE Iberia, Spain) are spinel ± plagioclase lherzolite, with minor harzburgite and wehrlite, displaying porphyroclastic or equigranular textures. Equigranular peridotites have olivine crystal preferred orientation (CPO) patterns similar to those of porphyroclastic xenoliths but slightly more dispersed. Olivine CPO shows [100]‐fiber patterns characterized by strong alignment of [100]‐axes subparallel to the stretching lineation and a girdle distribution of [010]‐axes normal to it. This pattern is consistent with simple shear or transtensional deformation accommodated by dislocation creep. One xenolith provides evidence for synkinematic reactive percolation of subduction‐related Si‐rich melts/fluids that resulted in oriented crystallization of orthopyroxene. Despite a seemingly undeformed microstructure, the CPO in orthopyroxenite veins in composite xenoliths is identical to those of pyroxenes in the host peridotite, suggesting late‐kinematic crystallization. Based on these observations, we propose that the annealing producing the equigranular microstructures was triggered by melt percolation in the shallow subcontinental lithospheric mantle coeval to the late Neogene formation of veins in composite xenoliths. Calculated seismic properties are characterized by fast propagation of P waves and polarization of fast S waves parallel to olivine [100]‐axis (stretching lineation). These data are compatible with present‐day seismic anisotropy observations in SE Iberia if the foliations in the lithospheric mantle are steeply dipping and lineations are subhorizontal with ENE strike, implying dominantly horizontal mantle flow in the ENE‐WSW direction within vertical planes, that is, subparallel to the paleo‐Iberian margin. The measured anisotropy could thus reflect a lithospheric fabric due to strike‐slip deformation in the late Miocene in the context of WSW tearing of the subducted south Iberian margin lithosphere.
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