The Relationship of Ultrasonic Velocities to c-axis Fabrics and Relaxation Characteristics of Ice Cores from Byrd Station, Antarctica

Abstract Deep cores from Byrd Station were used to calibrate an ultrasonic technique of evaluating crystal anisotropy in the Antarctic ice sheet. Velocities measured parallel ( V p ↓) and perpendicular ( V p →) to the vertical axis of the cores yielded data in excellent agreement with the observed c...

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Bibliographic Details
Published in:Journal of Glaciology
Main Authors: Gow, A. J., Kohnen, H.
Format: Article in Journal/Newspaper
Language:English
Published: Cambridge University Press (CUP) 1979
Subjects:
Online Access:http://dx.doi.org/10.1017/s0022143000014702
https://www.cambridge.org/core/services/aop-cambridge-core/content/view/S0022143000014702
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Summary:Abstract Deep cores from Byrd Station were used to calibrate an ultrasonic technique of evaluating crystal anisotropy in the Antarctic ice sheet. Velocities measured parallel ( V p ↓) and perpendicular ( V p →) to the vertical axis of the cores yielded data in excellent agreement with the observed c -axis fabric profile and with the in-situ P-wave velocity profile measured parallel to the bore-hole axis by Bentley. Velocity differences Δ V ( ΔV = V p ↓ – V p →) in excess of 140 m s −1 for cores from below 1300 m attest to the tight clustering of c -axes of crystals about the vertical, especially in the zone 1 300-1800 m. A small but significant decline in V p ↓ with ageing of the core, as deduced from Bentley’s down-hole data, is attributed to the formation of oriented cracks that occur in the ice cores as they relax from environmental stresses. This investigation of cores from the 2164 m thick ice sheet at Byrd Station establishes the ultrasonic technique as a viable method of monitoring relaxation characteristics of drilled cores and for determining the gross trends of c -axis orientation in ice sheets. The Byrd Station data, in conjunction with Barkov’s investigation of deep cores from Vostok, East Antarctica, also indicate that crystal anisotropy in the Antarctic ice sheet is dominated by a clustering of c -axes about a vertical symmetry axis.