(Table 2) Petrophysical, petrological, and geochemical characteristics of ODP Hole 163-990A sediments

Ocean Drilling Program Hole 990A penetrated 131 m of subaerially emplaced Paleocene flood basalts on the Southeast Greenland margin with a recovery of 74%. Shipboard P-wave velocity (Vp), density, and magnetic susceptibility were measured with 2- to 15-cm intervals on the core. Individual flow units...

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Bibliographic Details
Main Authors: Planke, Sverre, Cerney, Brian, Bücker, Christian J, Nilsen, Odd
Format: Dataset
Language:English
Published: PANGAEA 1999
Subjects:
163-990A
Aluminium oxide
Bartington MS2 magnetic susceptibility meter
Calcium oxide
Calculated
Clay minerals
Clinopyroxene
Density
dry bulk
wet bulk
Depth
relative
sediment/rock
DRILL
Drilling/drill rig
DSDP/ODP/IODP sample designation
Elements
total
Factor
Greenland Sea
Hamilton frame velocimeter
Boyce (1976)
Hysteresis
saturation remanence
per unit volume
Iron oxide
Fe2O3
Joides Resolution
Leg163
Lithologic unit/sequence
Loss on ignition
MAG
Magnesium oxide
Magnetic susceptibility
Magnetometer
Manganese oxide
Minerals
Number
Ocean Drilling Program
ODP
Olivine
Phosphorus pentoxide
Porosity
Potassium oxide
Sample code/label
Silicon dioxide
Sodium oxide
Greenland
Online Access:https://doi.pangaea.de/10.1594/PANGAEA.804639
https://doi.org/10.1594/PANGAEA.804639
Description
Summary:Ocean Drilling Program Hole 990A penetrated 131 m of subaerially emplaced Paleocene flood basalts on the Southeast Greenland margin with a recovery of 74%. Shipboard P-wave velocity (Vp), density, and magnetic susceptibility were measured with 2- to 15-cm intervals on the core. Individual flow units were divided into four zones based on the observed petrophysical characteristics. From the top, these are Zone I (<7 m thick with a Vp of ~2.5 km/s), Zone II (3-5 m thick with a strongly increasing Vp from 2.5 to 5.5 km/s), Zone III (up to 20 m thick with a Vp of ~5.5-6.0 km/s), and Zone IV (<2 m thick with a strongly decreasing Vp from 6.0 to 2.5 km/s). Eighteen samples were selected from three of the fourteen penetrated basalt units for geochemical, petrological, and petrophysical studies focusing on the altered, low-velocity upper lava Zones I and II. Zone I is strongly altered to >50% clay minerals (smectite) and iron hydroxides, and the petrophysical properties are primarily determined by the clay properties. Zone II is intermediately altered with 5%-20% clay minerals, where the petrophysical properties are a function of both the degree of alteration and porosity variations. Shipboard and shore-based measurements of the same samples show that storage permanently lowers the elastic moduli of basalt from Zones I to III. This is related to the presence of even small quantities of swelling clays. The data show that alteration processes are important in determining the overall seismic properties of flood basalt constructions. The degree and depth of alteration is dependent on the primary lava flow emplacement structures and environment. Thus, the interplay of primary emplacement and secondary alteration structures determine the elastic properties of basalt piles. Rock property theories for sand-clay systems are further used to model the physical property variations in these altered crystalline rocks.

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