Sound Speed, Reflectivity, Absorption, amd Thermal Diffusivity Measurements in Arctic Ice in 1990

Detailed measurements of internal properties of Arctic ice were made in Spring 1990 to relate acoustic properties to the physical properties of the ice. This report presents the procedures, analyses, and results of those studies. Some basic parameters measured in previous field studies were remeasur...

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Bibliographic Details
Main Authors: Garrison, G. R., Williams, K. L., Mourad, P. D., Francois, R. E., Wen, T.
Other Authors: WASHINGTON UNIV SEATTLE APPLIED PHYSICS LAB
Format: Text
Language:English
Published: 1993
Subjects:
Snow
Ice and Permafrost
Acoustic Detection and Detectors
Acoustics
*ACOUSTIC VELOCITY
*ACOUSTIC PROPERTIES
*SEA ICE
TEMPERATURE
THICKNESS
MONITORING
CONDUCTIVITY
INTERFACES
LAYERS
PHYSICAL PROPERTIES
REFLECTION
POROSITY
CONSISTENCY
THERMISTORS
FREEZING
ICE
THERMAL CONDUCTIVITY
PRESSURE
SOUND
CANOPIES
TRANSDUCERS
ABSORPTION
ACOUSTIC ATTENUATION
HYDROPHONES
REFLECTIVITY
DIFFUSIVITY
MELTING POINT
ARCTIC REGIONS
ICE WATER INTERFACE
ICE CANOPIES
Arctic
Ice
permafrost
Sea ice
Online Access:http://www.dtic.mil/docs/citations/ADA274326
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA274326
Description
Summary:Detailed measurements of internal properties of Arctic ice were made in Spring 1990 to relate acoustic properties to the physical properties of the ice. This report presents the procedures, analyses, and results of those studies. Some basic parameters measured in previous field studies were remeasured; consistency between individual experiments strengthens our confidence in the results and the techniques used. Novel techniques were used to measure properties of growing ice, which was later cored, submerged, and remeasured. Results reported here have been summarized in the open literature (Williams et al., J. Acoust. Soc. Am., 92, 2075, 1992). The basic data and their processing are described here in detail. In the ice-growth and submergence study, a 2-m-square hole was cut though the ice canopy. Strings of hydrophones and thermistors were then suspended vertically in the hole, and the water froze around them. Frequent monitoring of ice temperature and the receipt of sound pulses from below, along with salinities determined from ice cores obtained a short distance away, gave insight into the freezing process and the formation of a skeletal layer above the ice/water interface. Periodic measurements of the reflectivity of the growing ice at 37-150 kHz gave further information on the skeletal structure. The sound speed in the skeletal layer varied from that of the water at the ice-/water interface to that of bulk ice at about 3 cm into the ice. Absorption of sound (in decibels per meter) was about three times greater near the interface, decreasing to that for bulk ice at 15-20 cm into the ice. Ice acoustic properties, Reflection, Sound speed, Attenuation, Ice bulk properties, Porosity, Thermal conductivity.

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