T42C-04
Deep structure of Porcupine Basin and nature of the Porcupine Median Ridge from seismic refraction tomography
Thursday, 17 December 2015: 11:05
304 (Moscone South)
Louise Watremez1, Chen Chen1,2, Manel Prada3, Timothy A Minshull1, Brian O'Reilly3, Timothy J Reston4, Gerlind Wagner5, Viola Gaw5, Dirk Klaeschen5 and Patrick Shannon6, (1)University of Southampton, Southampton, United Kingdom, (2)National Oceanography Centre, Southampton, United Kingdom, (3)Dublin Institute for Advanced Studies, Dublin, Ireland, (4)University of Birmingham, Birmingham, United Kingdom, (5)Geomar Helmholtz Centre for Ocean Research, Kiel, Germany, (6)School of Earth Sciences, University College Dublin, Dublin, Ireland
Abstract:
The Porcupine Basin is a narrow V-shaped failed rifted basin located offshore SW Ireland. It is of Permo-Triassic to Cenozoic age, with the main rifting phase in the Late Jurassic to Early Cretaceous. Porcupine Basin is a key study area to learn about the processes of continental extension and to understand the thermal history of this rifted basin. Previous studies show increasing stretching factors, from less than 1.5 to the North to more than 6 to the South. A ridge feature, the Porcupine Median Ridge, has been identified in the middle of the southernmost part of the basin. During the last three decades, this ridge has been successively interpreted as a volcanic structure, a diapir of partially serpentinized mantle, or a block of continental crust. Its nature still remains debated today. In this study, we use arrival times from refractions and wide-angle reflections in the sedimentary, crustal and mantle layers to image the crustal structure of the thinnest part of the basin, the geometry of the continental thinning from margin to margin, and the Porcupine Median Ridge. The final velocity model is then compared with coincident seismic reflection data. We show that (1) the basin is asymmetric, (2) P-wave velocities in the uppermost mantle are lower than expected for unaltered peridotites, implying upper-mantle serpentinisation, (3) the nature of Porcupine Median Ridge is probably volcanic, and (4) the amount of thinning is greater than shown in previous studies. We discuss the thermal implications of these results for the evolution of this rift system and the processes leading to the formation of failed rifts. This project is funded by the Irish Shelf Petroleum Studies Group (ISPSG) of the Irish Petroleum Infrastructure Programme Group 4.