LEG 102

The Bermuda Rise


During the 15 years of the Deep Sea Drilling Project, significant basement penetration (> 500 m) was achieved at several sites in the ocean basins. Although comprehensive borehole geophysical measurements were successfully conducted at only two sites, both young crustal sites (6.2 Ma), these measurements are of landmark importance. There is, however, strong evidence that old crust is profoundly different from young crust and the primary objective of Leg 102 was the acquisition of a comprehensive baseline suite of borehole geophysical data in old oceanic crust (110 Ma).

Original DSDP Hole 418A was reentered and logged to a depth of 0.5 km into basement during Leg 102. Acoustic velocity and waveform logs showed relatively high compressional and shear wave velocities throughout the upper 500 m of layer 2 (the oceanic crust), with slow values occurring in the predominantly weathered pillow basalt and breccia units and fast values in the massive basalts. A similar difference was shown by induction and focused electrical resistivity logs. The upper 500 m below the sea floor was distinguished by unusually high gamma ray activity and relatively high formation porosities, as determined by density and neutron porosity logs. The base of this section was marked by a sharp magnetic polarity reversal, followed by a notable low on the magnetic susceptibility log from 500 to 600 mbsf, then a gradual increase to the bottom of the log. Temperature measurements indicated conductive rather than convective heat flow, suggesting a less active hydrothermal regime, a view supported by the water chemistry which, in contrast to the surrounding rocks, showed borehole water to be enriched in Ca2+ and depleted in Mg2+ and K+.

Upon completion of Leg 102 operations at DSDP Site 418, it was tentatively concluded that the properties of old oceanic crust are very different from young crust because of alteration and infilling of void space with age. Old crust at these sites has been sealed by alteration products, such as clays and carbonates, within the pillow basalt units and between layers of pillow and massive basalt, restricting the movement of pore water and causing geophysical layer 2A now to be absent. This is in contrast to observations at DSDP/ODP Hole 504B in young crust in the Pacific; layer 2A is still present, the upper basalt is relatively porous and permeable, and observed underpressures and flow of seawater into the upper permeable zone suggest weak hydrothermal convection within the pillow basalts.