New, high resolution swath bathymetry of Gettysburg and Ormonde Seamounts (Gorringe Bank, eastern Atlantic) and first geological results

DTM reveals for the Gettysburg Seamount an almost perfectly circular summit resulting from the blanket of bioclastic sediments over an igneous 'core' consisting of sheared and foliated serpentinites. The core is dissecated by N 10 degrees W trending ridges elevating some tens of metres and filled in between by bioclastic sands. Both foliation and ridge patterns seem related to primary igneous fabric rather than later structural deformation. The overall circular shape confirms the origin of the seamount as a mantle serpentinite diapir in analogy with similar, but subduction-related, circular seamounts observed in the Bonin Trench ( western Pacific). In contrast the Ormonde elongated summit follows the regional tectonic trend with a N 60 degrees E active ( seismogenic?) fault on its southeastern flank. Its basement morphology corresponds to the outcrops of igneous rocks chiefly consisting of gabbros, volcanic rocks and dyke intrusions. On both seamounts topographic profiles show that the 'shelf' area is somewhat convex rather than flat like that of 'Pacific type' guyots and is bordered by a depositional, locally erosional shelf break, located between - 170 and - 130 m. Various terraced surfaces and some geological evidence confirm previous observations and indicate relative sea-level oscillations with partial emersion of the two summits that seem occurred during the last glacial cycle ( past 120 ka).

High resolution swath bathymetry of shallow water (< 200 m) oceanic seamounts is a relatively rare issue. During the recent Gorringe_ 2003 cruise over the Gorringe Bank ( Eastern Atlantic) we collected multibeam bathymetry on the bank's two shallow summits, Gettysburg and Ormonde in the - 25/- 400 m depth range at a resolution rarely achieved over an oceanic seamount. We also carried out bottom samplings and ROV dives in the same bathymetric interval. The acquisition parameters and the characteristics of the echosounder employed allowed to generate a Digital Terrain Model (DTM) with metric spatial resolution upto 75 - 100 m depths. To ensure proper tidal corrections a tide-gauge was deployed at sea-bottom during the survey.