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Bends, sedimentary basins and earthquake hazards |
1 Instituto Geológico y Minero de España. C/ La Calera, 1, 28760, Tres Cantos, Madrid, Spain (e-mail: f.bohoyo{at}igme.es)
2 Departamento de Geodinámica, Universidad de Granada. 18071 Granada, Spain
3 Instituto Andaluz Ciencias de la Tierra, CSIC/Universidad Granada. Facultad de Ciencias, 18002 Granada, Spain
4 P. P. Shirshov Institute of Oceanology, Russian Academy of Sciences, 23, Krasikova 117218 Moscow, Russia
5 Departament de Geologia Dinàmica i Geofísica, Universitat de Barcelona, 08028 Barcelona, Spain
6 Geological Science Division. British Antarctic Survey, High Cross, Mandigley Road, Cambridge, CB3 0ET, UK (e-mail: fbo{at}pcmail.nerc-bas.ac.uk)
The Scotia–Antarctic plate boundary extends along the southern branch of the Scotia Arc, between triple junctions with the former Phoenix plate to the west (57°W) and with the Sandwich plate to the east (30°W). The main mechanism responsible for the present arc configuration is the development of the Scotia and Sandwich plates from 30–35 Ma, related to breakup of the continental connection between South America and the Antarctic Peninsula. The Scotia–Antarctic plate boundary is a very complex tectonic zone, because both oceanic and continental elements are involved. Present-day sinistral transcurrent motion probably began 8 Ma ago. The main active structures that we observed in the area include releasing and restraining bends, with related deep extensional and compressional basins, and probable pull-apart basins. The western sector of the plate boundary crosses fragmented continental crust: the Western South Scotia Ridge, with widespread development of pull-apart basins and releasing bends deeper than 5000 m, filled by asymmetrical sedimentary wedges. The northern border of the South Orkney microcontinent, in the central sector, has oceanic and continental crust in contact along a large thrust zone. Finally, the eastern sector of the South Scotia Ridge is located within Discovery Bank, a piece of continental crust from a former arc. On its southern border, strike-slip and normal faults produce a 5500-m-deep trough that may be interpreted as a pull-apart basin. In the eastern and western South Scotia Ridge, despite extreme continental-crustal thinning, the basins show no development of oceanic crust. This geometry is conditioned by the distinctive rheological behaviour of the crust involved, with the bulk concentration of deformation within the rheologically weaker continental blocks.
