Velocity anisotropy in calcareous sediments from Leg 130, Ontong Java Plateau

Citation data:

Proceedings of the Integrated Ocean Drilling Program

Publication Year:
1993
Usage 87
Downloads 83
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Repository URL:
https://scholars.unh.edu/ccom_affil/24
Author(s):
Bassinot, Frank; Marsters, Janice C.; Mayer, Larry A.; Wilkens, Roy H.
Publisher(s):
International Ocean Discovery Program
Tags:
07 Marine Geology and Oceanography; 20 Geophysics; Applied Anisotropy; biogenic structures; bioturbation; body waves; calcareous composition; carbonate rocks; chalk; clastic sediments; elastic waves; Leg 130; measurement; Ocean Drilling Program; Ontong Java Plateau; ooze; P-waves; Pacific Ocean; sedimentary rocks; sedimentary structures; sediments; seismic waves; transition zones; velocity; West Pacific; Geology; Oceanography and Atmospheric Sciences and Meteorology; Stratigraphy
conference paper description
During Leg 130, an intensive program of P-wave velocity measurements was conducted on calcareous sediments of varying induration (ranging from ooze to limestone) that cover the Ontong Java Plateau (west equatorial Pacific). The high quantity and quality of shipboard acoustical property measurements seemed to be particularly appropriate for gaining a better understanding of acoustic anisotropy in calcareous sediments. Major results can be summarized as follows: 1. In calcareous oozes, acoustic anisotropy exists even at shallow depths of burial. Values are low, ranging from -0.5% to 3.5% and averaging 1.2%. Anisotropy profiles are affected by coring disturbances, but they still roughly correlate between holes cored at a same site. There is no general increase of anisotropy with depth of burial in ooze sections. These observations imply that most of the anisotropy measured in oozes is controlled by original changes in sediment composition rather than by reorientation of anisotropic minerals or flattening of pores during burial. Given the data available, bedding lamination seems to be the most satisfactory explanation for acoustic anisotropy in calcareous oozes of Ontong Java Plateau. However, bioturbation affects the entire ooze sections cored and much of the original depositional features may have been removed. Further analysis such as scanning-electron-microscope (SEM) observations of epoxy impregnated ooze samples are necessary to test the "bedding lamination" hypothesis. 2. Ooze to chalk transition is marked by a tremendous change in the anisotropy profiles. In chalk sections the anisotropy values are higher (reaching 20%) than in ooze sections. Most of the anisotropies are negative (horizontal P-wave velocities lower than vertical velocities), whereas positive values are expected. Weakly cemented chalk samples are affected by cracking when compressed between the Hamilton Frame transducers for P-wave measurement. Cracks occur along bedding planes during horizontal P-wave velocity measurements, thus leading to anomalously low horizontal P-wave velocities and negative anisotropies.