ALBERT

Description: Abundant Fe-Mn carbonate concretions (mainly siderite, manganosiderite, and rhodochrosite) were found in the hemipelagic claystones of Site 603 on the eastern North American continental rise. They occur as nodules, micronodules, or carbonate-replaced burrow fills and layers at a subbottom depth of between ~ 120 (Pliocene) and 1160 m (Albian-Cenomanian). In general, the Fe-Mn carbonate concretions form from CO3- produced by the microbiological degradation of organic matter in the presence of abundant Fe + or Mn + and very low S- concentrations. However, there is also some evidence for diagenetic replacement of preexisting calcite by siderite. The carbon isotope composition of diagenetic Fe-Mn carbonate nodules is determined by CO2 reduction during methanogenesis. Carbonate nodules in Cretaceous sediments at sub-bottom depths of 1085 and 1160 m have distinctly lower d13C values (– 12.2 and - 12.9 per mil) than Neogene siderites, associated with abundant biogenic methane in the pore space (-8.9 to 1.7 per mil between 330 and 780 m depth). Since no isotopic zonation could be detected within individual nodules, we assume that the isotopic composition reflects more or less geochemical conditions at the present burial depth of the carbonate nodules. Carbonates did not precipitate within the zone of sulfate reduction (approximately 0.01 to 10 m), where all of the pyrite was formed. The oxygen isotope composition indicates precipitation from seawater-derived interstitial waters. The d18O values decrease with increasing burial depth from + 5.1 to - 1.2 per mil, suggesting successively higher temperatures during carbonate formation.

Description: A new WHOI heat flow instrument was successfully used in conjunction with the hydraulic piston corer to obtain temperature-time records for three depths at DSDP Site 587. In order to arrive at an estimate for in situ, steady-state temperature, these data are applied to a two-dimensional theoretical formulation that describes the cooling behaviour of an annular cylinder surrounded by sediment. An average heat flow of 56.9 mW/m**2 is computed from the resulting temperature profile. This value is in close agreement with the theoretical heat flux of 53.0 mW/m**2 determined from the general heat flow-age relationship. The temperature profile at Site 587 is nonlinear. Examination of the effects of sudden changes in bottom water temperature and upward movement of pore fluid fails to provide convincing solutions to the cause of this nonlinearity. Knowing sediment permeability and extending the theoretical data analysis to three dimensions would improve our ability to understand the geothermal environment at this location.

Description: Evidence of considerable overpressuring of pore fluids in the sediment drilled during Leg 84 was obtained from direct measurement of pressure by two methods. The first involved measurement of back pressure when the annulus of the drill hole became constricted with unremoved drill cuttings or constriction was caused by plastic inflow of the drill hole walls. The second involved measurement of pressure ahead of the bit in conjunction with in situ water samples and heat flow. All measurements indicated abnormally high pore pressure even in slope deposits of the Middle America Trench off Guatemala.