Antoine Triantafyllou

Deformation-driven Differentiation during in situ Crystallization of the 2·7 Ga Iguilid Mafic Intrusion (West African Craton, Mauritania)

The 2 7 Ga Iguilid mafic intrusion is a post-metamorphic plutonic body made of cumulate gabbronorite and norite characterized by limited variations in modal proportions but significant disparities in trace element contents. The cumulates display microtextural evidence for syn-magmatic deformation, leading to reorientation of cumulus minerals, indented contacts at plagioclase grain boundaries, local bending and fracturing of euhedral cumulus plagioclase and interstitial melt migration/ segregation structures. All these features suggest that the Iguilid intrusion formed after in situ crystallization and syn-magmatic deformation of an unconsolidated mush within solidification fronts. Quantitative investigations of syn-magmatic fabrics together with geochemical estimations of the trapped melt fraction reveal a strong inverse correlation between the anisotropy degree P and the volume of trapped liquid retained in the cumulates. We interpret the dominantly vertical planar and linear fabrics in the Iguilid rocks as a result of horizontal shortening of the cumulates induced by filter pressing of a partly solidified mush against the vertical walls of the intrusion. Flattening of the cumulates occurred in response either to a syn-magmatic rotation of the Iguilid body relative to the tectonic main stress or to stages of overand under-pressurization owing to cycles of magma recharge or discharge. Deformation of the unconsolidated cumulates led to migration of the silicic interstitial melt and controlled their bulk content in incompatible elements. This migrating liquid had similar trace element and isotopic compositions to synchronous 2 7 Ga dioritic to granodioritic plutons, forming a bimodal, post-metamorphic, magmatic suite with the Iguilid body. The interstitial melt extracted from the Iguilid mafic intrusion could have fed synchronous metaluminous intermediate to felsic plutons.

Geolokit: An interactive tool for visualising and exploring geoscientific data in Google Earth

Abstract Virtual globes have been developed to showcase different types of data combining a digital elevation model and basemaps of high resolution satellite imagery. Hence, they became a standard to share spatial data and information, although they suffer from a lack of toolboxes dedicated to the formatting of large geoscientific dataset. From this perspective, we developed Geolokit: a free and lightweight software that allows geoscientists – and every scientist working with spatial data – to import their data (e.g., sample collections, structural geology, cross-sections, field pictures, georeferenced maps), to handle and to transcribe them to Keyhole Markup Language (KML) files. KML files are then automatically opened in the Google Earth virtual globe and the spatial data accessed and shared. Geolokit comes with a large number of dedicated tools that can process and display: (i) multi-points data, (ii) scattered data interpolations, (iii) structural geology features in 2D and 3D, (iv) rose diagrams, stereonets and dip-plunge polar histograms, (v) cross-sections and oriented rasters, (vi) georeferenced field pictures, (vii) georeferenced maps and projected gridding. Therefore, together with Geolokit, Google Earth becomes not only a powerful georeferenced data viewer but also a stand-alone work platform. The toolbox (available online at http://www.geolokit.org ) is written in Python, a high-level, cross-platform programming language and is accessible through a graphical user interface, designed to run in parallel with Google Earth, through a workflow that requires no additional third party software. Geolokit features are demonstrated in this paper using typical datasets gathered from two case studies illustrating its applicability at multiple scales of investigation: a petro-structural investigation of the Ile d’Yeu orthogneissic unit (Western France) and data collection of the Mariana oceanic subduction zone (Western Pacific).