Sofar Channel Axial Sound Speed and Depth in the Atlantic Ocean

Northrop, John; Colborn, Jennifer

doi:10.1121/1.2033183

Cited by 3 publications

(4 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, the RAM model predicts that acoustic phases partially propagate as surface reflected waves south of the 60°S parallel, thereby evading bathymetric obstruction and reducing the average effect of acoustic blockage to ~10 dB re 1 μPa. This upward shift of the axis of the SOFAR channel is facilitated by the temperature anomaly of the ACC, which dilutes vertical sound speed gradients in the upper layers and subsequently raises the minimum velocity zone to shallower depths of up to 300 m and less (e.g., Northrop and Colborn [1974] and de Groot‐Hedlin et al [2009]; see also Figure S3). Similar effects of range‐dependent temperature variations on high‐latitude acoustic propagation have been previously observed by Chapp et al [2005], enabling long‐distance detection of iceberg‐generated tremor in the southern Indian Ocean.…”

Section: Investigation Of Potential Bathymetric Blockage and Transmismentioning

confidence: 99%

Ultra‐long‐range hydroacoustic observations of submarine volcanic activity at Monowai, Kermadec Arc

Metz

Watts

Grevemeyer

et al. 2016

Geophysical Research Letters

View full text Add to dashboard Cite

Monowai is an active submarine volcanic center in the Kermadec Arc, Southwest Pacific Ocean. During May 2011, it erupted over a period of 5 days, with explosive activity directly linked to the generation of seismoacoustic T phases. We show, using cross‐correlation and time‐difference‐of‐arrival techniques, that the eruption is detected as far as Ascension Island, equatorial South Atlantic Ocean, where a bottom moored hydrophone array is operated as part of the International Monitoring System of the Comprehensive Nuclear‐Test‐Ban Treaty Organization. Hydroacoustic phases from the volcanic center must therefore have propagated through the Sound Fixing and Ranging channel in the South Pacific and South Atlantic Oceans, a source‐receiver distance of ~15,800 km. We believe this to be the furthest documented range of a naturally occurring underwater signal above 1 Hz. Our findings, which are consistent with observations at regional broadband stations and long‐range, acoustic parabolic equation modeling, have implications for submarine volcano monitoring.

show abstract

Section: Investigation Of Potential Bathymetric Blockage and Transmismentioning

confidence: 99%

Ultra‐long‐range hydroacoustic observations of submarine volcanic activity at Monowai, Kermadec Arc

Metz

Watts

Grevemeyer

et al. 2016

Geophysical Research Letters

View full text Add to dashboard Cite

show abstract

“…Hydroacoustic signals can propagate in a waveguide known as the sound‐fixing and ranging (SOFAR) channel which is a low‐velocity zone present in the ocean at low‐to‐mid latitudes. The axis of the SOFAR channel is ∼1 km deep near the equator and tropics and becomes shallower with increasing latitude (e.g., Northrop & Colborn, 1974). This waveguide combined with the low attenuation of sound in water allows hydroacoustic signals to travel across, and even between, ocean basins (e.g., Bryan et al., 1963; Ewing & Worzel, 1948) with a few detections of submarine eruptions at distances >14,000 km (Dziak & Fox, 2002; Metz et al., 2016; Tepp, Chadwick, et al., 2019).…”

Section: Introductionmentioning

confidence: 99%

The Seismo‐Acoustics of Submarine Volcanic Eruptions

Tepp

Dziak

2021

JGR Solid Earth

View full text Add to dashboard Cite

Many of the world’s volcanoes are hidden beneath the ocean’s surface where eruptions are difficult to observe. However, seismo‐acoustic signals produced by these eruptions provide a useful means of identifying active submarine volcanism. A literature survey revealed reports of 119 seismo‐acoustically recorded submarine eruptions since 1939. Submarine eruptions have been recorded in all major tectonic settings, with a range of geochemistries, and at a variety of water depths, but the reports are dominated by eruptions in the Pacific and at only a few locations. Many of the reports offer little detail, with over half of the observations made from distances >500 km, and only about half were confirmed as eruptions by non‐seismo‐acoustic evidence. The reported seismo‐acoustic signals cover a wide variety of processes, including earthquakes, explosions, various types of tremor, signals related to lava extrusion, and landslides. Recorded signals can sometimes be difficult to classify or confidently associate with an eruption, although there has been progress in this regard. Real‐time monitoring of submarine eruptions has been on‐going for several decades on regional and global scales with growing interest and effort in local networks. Real‐time networks are complemented by short‐term instrument deployments that often give more detailed insights into the dynamics and processes of submarine eruptions. Thorough seismo‐acoustic monitoring and study has increased our understanding of submarine eruptions, especially of deep‐sea volcanoes and spreading centers. Despite this, there are still many outstanding questions that need to be addressed for submarine volcanoes to be as well understood and monitored as their terrestrial counterparts.

show abstract

“…The shape and absolute values of this trend are similar to the other results. 31 The latter are obtained with active experiments. Another experiment with SOFAR floats 32 also actively probed the deep ocean's propagation velocity of acoustic waves.…”

Section: Discussionmentioning

confidence: 97%

“…Such values, as obtained in this study, are not in agreement with other studies. 12,31 The celerity is underestimated because the propagation path is longer than the epicentral distance.…”

Section: Discussionmentioning

confidence: 98%

Passive probing of the sound fixing and ranging channel with hydro-acoustic observations from ridge earthquakes

Evers

Snellen

2015

The Journal of the Acoustical Society of America

View full text Add to dashboard Cite

The International Monitoring System includes a hydro-acoustic part to verify the Comprehensive Nuclear-Test-Ban Treaty. Besides explosive signals, monitoring stations also detect acoustic waves from earthquakes that travel through the SOund Fixing And Ranging (SOFAR) channel. The travel times of such detections are listed in the Reviewed Event Bulletin, which is statistically evaluated for the stations located in the Pacific, Indian, and Atlantic Oceans. The celerities of ridge earthquakes are calculated to build up a homogeneous data-set, based on similar source mechanisms. The celerity is defined as the epicentral distance divided by the travel time. The global characteristics of these celerities can be well understood in terms of temperature variations in the SOFAR channel. A detailed velocity profile has been retrieved for the Atlantic Ocean where large differences (14 m/s) are found between the southern and northern parts of the basin. Propagation modeling with normal modes supports these findings, which shows that the celerity gives an estimate of the sound speed in the SOFAR channel. These results compare remarkably well with those from active experiments, showing the ability of passively probing the SOFAR channel with hydro-acoustic waves from earthquake sources.

show abstract

Sofar Channel Axial Sound Speed and Depth in the Atlantic Ocean

Cited by 3 publications

References 19 publications

Ultra‐long‐range hydroacoustic observations of submarine volcanic activity at Monowai, Kermadec Arc

Ultra‐long‐range hydroacoustic observations of submarine volcanic activity at Monowai, Kermadec Arc

The Seismo‐Acoustics of Submarine Volcanic Eruptions

Passive probing of the sound fixing and ranging channel with hydro-acoustic observations from ridge earthquakes

Contact Info

Product

Resources

About