Abstract

SUMMARY The Mid-Atlantic Ridge at 13°N is regarded as a type locality for oceanic core complexes (OCCs), as it contains, within ∼70 km along the spreading axis, four that are at different stages of their life cycle. The wealth of existing seabed observations and sampling makes this an ideal target to resolve contradictions between the existing models of OCC development. Here we describe the results of P-wave seismic tomographic modelling within a 60 × 60 km footprint, containing several OCCs, the ridge axis and both flanks, which determines OCC crustal structure, detachment geometry and OCC interconnectivity along axis. A grid of wide-angle seismic refraction data was acquired along a series of 17 transects within which a network of 46 ocean-bottom seismographs was deployed. Approximately 130 000 first arrival traveltimes, together with sparse Moho reflections, have been modelled, constraining the crust and uppermost mantle to a depth of ∼10 km below sea level. Depth slices through this 3-D model reveal several independent structures each with a higher P-wave velocity (Vp) than its surrounds. At the seafloor, these features correspond to the OCCs adjacent to the axial valley walls at 13°20′N and 13°30′N, and off axis at 13°25′N. These high-Vp features display dipping trends into the deeper crust, consistent with the surface expression of each OCC's detachment, implying that rocks of the mid-to-lower crust and uppermost mantle within the footwall are juxtaposed against lower Vp material in the hangingwall. The neovolcanic zone of the ridge axis has systematically lower Vp than the surrounding crust at all depths, and is wider between OCCs. On average, throughout the 13°N region, the crust is ∼6 km-thick. However, beneath a deep lava-floored basin between axial OCCs the crust is thinner and is more characteristically oceanic in layering and velocity–depth structure. Thicker crust at the ridge axis suggests a more magmatic phase of current crustal formation, while modelling of the sparse Moho reflections suggests the crust–mantle boundary is a transition zone throughout most of the 13°N segment. Our results support a model in which OCCs are bounded by independent detachment faults whose dip increases with depth and is variable with azimuth around each OCC, suggesting a geometry and mechanism of faulting that is more complicated than previously thought. The steepness of the northern flank of the 13°20′N detachment suggests that it represents a transfer zone between different faulting regimes to the south and north. We propose that individual detachments may not be linked along-axis, and that OCCs act as transfer zones linking areas of normal spreading and detachment faulting. Along ridge variation in magma supply influences the nature of this detachment faulting. Consequently, not only does magma supply control how detachments rotate and migrate off axis before finally becoming inactive, but also how, when and where new OCCs are created.

Highlights

  • Slow-spreading ridges are traditionally characterized by a volcanic axial valley bounded by a symmetric set of inward-facing, low-offset normal faults

  • 6.1 Crustal structure Sub-seafloor variation in density throughout the 13N region is demonstrated by the free-air anomaly (FAA – Fig. 9b), the MBA (Fig. 9c) and to a lesser extent the residual mantle Bouguer anomaly (RMBA – Fig. 9d) which were calculated from ship meter data acquired during JC102, JC109 and JC132 following the approach outlined in Peirce et al (2019)

  • Our 3-D grid tomographic results support the local-scale hypothesis (MacLeod et al, 2009) in which oceanic core complexes (OCCs) are associated with independent detachment faults which result in asymmetric spreading across the ridge axis

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Summary

Introduction

Slow-spreading ridges are traditionally characterized by a volcanic axial valley bounded by a symmetric set of inward-facing, low-offset normal faults. Serpentinites, which reflect hydrothermally altered rocks of the lower crust/upper mantle, are commonly sampled on OCC detachment surfaces (Escartín et al, 1997, 2003a; Canales et al, 2004; Picazo et al, 2012; Hansen et al, 2013). These large-scale fault surfaces have been interpreted as the source of deep, high-angle, normal seismicity (e.g. deMartin et al, 2007), and are shown by palaeomagnetic studies to undergo significant footwall rotation close to the surface These observations support a model in which the curved, convex-up, gently-sloping

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