Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean

Our objectives were to conduct a series of calibration shots within and to the south of the ACC that would generate acoustic signals at frequencies f > 30 Hz and to analyze the signals recorded at hydrophone stations operated by the IMS. The overall goal was to compare observed source-receiver tr...

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Main Authors: Groot-Hedlin, Catherine de, Blackman, Donna K., Jenkins, C. S.
Other Authors: SCRIPPS INSTITUTION OF OCEANOGRAPHY LA JOLLA CA
Format: Text
Language:English
Published: 2008
Subjects:
Acoustics
*ACOUSTIC WAVES
*ANTARCTIC REGIONS
*ACOUSTIC SIGNALS
*PROPAGATION
TRANSMISSION LOSS
CONVERSION
PREDICTIONS
MODELS
MONITORING
UNDERWATER SOUND SIGNALS
NUMERICAL ANALYSIS
TRAVEL TIME
CALIBRATION
GROUND BASED
HYDROPHONES
CLIMATOLOGY
NUCLEAR EXPLOSIONS
FREQUENCY
DATA BASES
SYMPOSIA
*CIRCUMPOLAR CURRENT
Antarctic
Indian
Pacific
The Antarctic
Antarc*
Antarctica
Online Access:http://www.dtic.mil/docs/citations/ADA516246
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA516246
id ftdtic:ADA516246
record_format openpolar
spelling ftdtic:ADA516246 2023-05-15T13:48:25+02:00 Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean Groot-Hedlin, Catherine de Blackman, Donna K. Jenkins, C. S. SCRIPPS INSTITUTION OF OCEANOGRAPHY LA JOLLA CA 2008-09 text/html http://www.dtic.mil/docs/citations/ADA516246 http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA516246 en eng http://www.dtic.mil/docs/citations/ADA516246 Approved for public release; distribution is unlimited. DTIC Acoustics *ACOUSTIC WAVES *ANTARCTIC REGIONS *ACOUSTIC SIGNALS *PROPAGATION TRANSMISSION LOSS CONVERSION PREDICTIONS MODELS MONITORING UNDERWATER SOUND SIGNALS NUMERICAL ANALYSIS TRAVEL TIME CALIBRATION GROUND BASED HYDROPHONES CLIMATOLOGY NUCLEAR EXPLOSIONS FREQUENCY DATA BASES SYMPOSIA *CIRCUMPOLAR CURRENT Text 2008 ftdtic 2016-02-22T23:56:12Z Our objectives were to conduct a series of calibration shots within and to the south of the ACC that would generate acoustic signals at frequencies f > 30 Hz and to analyze the signals recorded at hydrophone stations operated by the IMS. The overall goal was to compare observed source-receiver travel times to the IMS hydrophone stations to those predicted by numerical models for paths crossing the Antarctic convergence zone and to use these results to determine the accuracy to which sources may be located within the ACC. A second goal was to compare observed vs. modeled transmission losses. The results of the second goal were reported last year; it was found that transmission loss is nearly uniform as a function of frequency for the shots examined in this study (de Groot-Hedlin et al., 2007; de Groot-Hedlin et al., 2008). Acoustic propagation for sources within the ACC is complicated by the sharp temperature gradient at the northern boundary. The ACC boundary separates cold waters that flow eastward around Antarctica from warmer subtropical waters to the north. The abrupt spatial variation in temperature and salinity results in strong gradients in the speed of acoustic waves through the ocean, which in turn deflects the path of propagating acoustic waves near the northern boundary of the ACC (Heaney et al., 1999). Furthermore, south of the ACC boundary, the low-velocity oceanic "sound channel" axis, that is typically 100's to 1,000-m-deep shoals and the overlying higher velocity layer thins to nothing over a short distance, resulting in sea surface-limited propagation. Therefore, the detailed structure of the ACC boundary is strongly affected by seasonal temperature variations that extend to depths of over 1 km. Dushaw et al., (1999) showed that this type of seasonal variability produces considerable seasonal differences in acoustic travel times for paths through the North Pacific. We conducted an experiment in December, 2006, to determine how well acoustic wave tra Presented at the Conference on Monitoring Research Review: Ground-Based Nuclear Explosion Monitoring Technologies (30th), held in Portsmouth, VA, on 23-25 Sep 2008. Published in the proceedings of the conference, p715-724, 2008. Prepared in cooperation with Naval Surface Warfare Center, Indian Head Division. Sponsored in part by the National Nuclear Security Administration (NNSA) and by the Army Space and Missile Defense Command. The original document contains color images. Text Antarc* Antarctic Antarctica Defense Technical Information Center: DTIC Technical Reports database Antarctic Indian Pacific The Antarctic
institution Open Polar
collection Defense Technical Information Center: DTIC Technical Reports database
op_collection_id ftdtic
language English
topic Acoustics
*ACOUSTIC WAVES
*ANTARCTIC REGIONS
*ACOUSTIC SIGNALS
*PROPAGATION
TRANSMISSION LOSS
CONVERSION
PREDICTIONS
MODELS
MONITORING
UNDERWATER SOUND SIGNALS
NUMERICAL ANALYSIS
TRAVEL TIME
CALIBRATION
GROUND BASED
HYDROPHONES
CLIMATOLOGY
NUCLEAR EXPLOSIONS
FREQUENCY
DATA BASES
SYMPOSIA
*CIRCUMPOLAR CURRENT
spellingShingle Acoustics
*ACOUSTIC WAVES
*ANTARCTIC REGIONS
*ACOUSTIC SIGNALS
*PROPAGATION
TRANSMISSION LOSS
CONVERSION
PREDICTIONS
MODELS
MONITORING
UNDERWATER SOUND SIGNALS
NUMERICAL ANALYSIS
TRAVEL TIME
CALIBRATION
GROUND BASED
HYDROPHONES
CLIMATOLOGY
NUCLEAR EXPLOSIONS
FREQUENCY
DATA BASES
SYMPOSIA
*CIRCUMPOLAR CURRENT
Groot-Hedlin, Catherine de
Blackman, Donna K.
Jenkins, C. S.
Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean
topic_facet Acoustics
*ACOUSTIC WAVES
*ANTARCTIC REGIONS
*ACOUSTIC SIGNALS
*PROPAGATION
TRANSMISSION LOSS
CONVERSION
PREDICTIONS
MODELS
MONITORING
UNDERWATER SOUND SIGNALS
NUMERICAL ANALYSIS
TRAVEL TIME
CALIBRATION
GROUND BASED
HYDROPHONES
CLIMATOLOGY
NUCLEAR EXPLOSIONS
FREQUENCY
DATA BASES
SYMPOSIA
*CIRCUMPOLAR CURRENT
description Our objectives were to conduct a series of calibration shots within and to the south of the ACC that would generate acoustic signals at frequencies f > 30 Hz and to analyze the signals recorded at hydrophone stations operated by the IMS. The overall goal was to compare observed source-receiver travel times to the IMS hydrophone stations to those predicted by numerical models for paths crossing the Antarctic convergence zone and to use these results to determine the accuracy to which sources may be located within the ACC. A second goal was to compare observed vs. modeled transmission losses. The results of the second goal were reported last year; it was found that transmission loss is nearly uniform as a function of frequency for the shots examined in this study (de Groot-Hedlin et al., 2007; de Groot-Hedlin et al., 2008). Acoustic propagation for sources within the ACC is complicated by the sharp temperature gradient at the northern boundary. The ACC boundary separates cold waters that flow eastward around Antarctica from warmer subtropical waters to the north. The abrupt spatial variation in temperature and salinity results in strong gradients in the speed of acoustic waves through the ocean, which in turn deflects the path of propagating acoustic waves near the northern boundary of the ACC (Heaney et al., 1999). Furthermore, south of the ACC boundary, the low-velocity oceanic "sound channel" axis, that is typically 100's to 1,000-m-deep shoals and the overlying higher velocity layer thins to nothing over a short distance, resulting in sea surface-limited propagation. Therefore, the detailed structure of the ACC boundary is strongly affected by seasonal temperature variations that extend to depths of over 1 km. Dushaw et al., (1999) showed that this type of seasonal variability produces considerable seasonal differences in acoustic travel times for paths through the North Pacific. We conducted an experiment in December, 2006, to determine how well acoustic wave tra Presented at the Conference on Monitoring Research Review: Ground-Based Nuclear Explosion Monitoring Technologies (30th), held in Portsmouth, VA, on 23-25 Sep 2008. Published in the proceedings of the conference, p715-724, 2008. Prepared in cooperation with Naval Surface Warfare Center, Indian Head Division. Sponsored in part by the National Nuclear Security Administration (NNSA) and by the Army Space and Missile Defense Command. The original document contains color images.
author2 SCRIPPS INSTITUTION OF OCEANOGRAPHY LA JOLLA CA
format Text
author Groot-Hedlin, Catherine de
Blackman, Donna K.
Jenkins, C. S.
author_facet Groot-Hedlin, Catherine de
Blackman, Donna K.
Jenkins, C. S.
author_sort Groot-Hedlin, Catherine de
title Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean
title_short Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean
title_full Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean
title_fullStr Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean
title_full_unstemmed Effects of Variability Associated with the Antarctic Circumpolar Current on Sound Propagation in the Ocean
title_sort effects of variability associated with the antarctic circumpolar current on sound propagation in the ocean
publishDate 2008
url http://www.dtic.mil/docs/citations/ADA516246
http://oai.dtic.mil/oai/oai?&verb=getRecord&metadataPrefix=html&identifier=ADA516246
geographic Antarctic
Indian
Pacific
The Antarctic
geographic_facet Antarctic
Indian
Pacific
The Antarctic
genre Antarc*
Antarctic
Antarctica
genre_facet Antarc*
Antarctic
Antarctica
op_source DTIC
op_relation http://www.dtic.mil/docs/citations/ADA516246
op_rights Approved for public release; distribution is unlimited.
_version_ 1766249224860598272

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