On acoustic transmission in ocean-surface waveguides

A sound speed profile which increases monotonically with depth below the ocean surface is upward-refractive, acting as a duct in which sound may be transmitted to long ranges with little attenuation. A well-known example is the mixed layer, in which the temperature is uniform and the sound speed app...

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Published in:Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences
Format: Article in Journal/Newspaper
Language:English
Published: The Royal Society 1991
Subjects:
Arctic Ocean
Online Access:http://dx.doi.org/10.1098/rsta.1991.0059
https://royalsocietypublishing.org/doi/pdf/10.1098/rsta.1991.0059
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spelling crroyalsociety:10.1098/rsta.1991.0059 2024-09-15T17:54:16+00:00 On acoustic transmission in ocean-surface waveguides 1991 http://dx.doi.org/10.1098/rsta.1991.0059 https://royalsocietypublishing.org/doi/pdf/10.1098/rsta.1991.0059 en eng The Royal Society https://royalsociety.org/journals/ethics-policies/data-sharing-mining/ Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences volume 335, issue 1639, page 513-555 ISSN 0962-8428 2054-0299 journal-article 1991 crroyalsociety https://doi.org/10.1098/rsta.1991.0059 2024-07-15T04:26:41Z A sound speed profile which increases monotonically with depth below the ocean surface is upward-refractive, acting as a duct in which sound may be transmitted to long ranges with little attenuation. A well-known example is the mixed layer, in which the temperature is uniform and the sound speed approximately scales with the hydrostatic pressure, increasing linearly with depth. The depth of the mixed layer depends on surface conditions, but is of the order of 100 m. Deeper channels are found in ice-covered polar waters, where the temperature and sound speed profiles both show a minimum at the surface. A typical surface duct in the Arctic Ocean may extend to depths of 1000 m or more and is capable of supporting very-low-frequency (VLF) (1-50 Hz) acoustic transmissions with no bottom interactions. On a depth scale that is smaller by several orders of magnitude, wave-breaking events create a bubbly layer one or two metres thick below the sea surface, with the highest concentration of bubbles, and correspondingly the lowest sound speed, at the surface. The bubble layer acts as a waveguide for sound in the audio frequency range, above 2 kHz, although transmission may be severely attenuated due to absorption and scattering by the bubbles, as well as by the irregular geometry of the sea surface and the bubble clouds. Most ocean-surface waveguides can be accurately represented by an inverse-square sound speed profile, which may be monotonic increasing (upward refracting) or decreasing (downward refracting) with depth, and whose detailed shape is governed by just three parameters. An analysis of the sound field below the sea surface in the presence of such a profile shows that it consists of a near-field component, given by a branch-line integral, plus a sum of uncoupled normal modes representing the trapped radiation which propagates to longer ranges. The modal contribution is identically zero in the case of the downward refracting profiles. The properties of the modes emerge from a straightforward theoretical ... Article in Journal/Newspaper Arctic Ocean The Royal Society Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences 335 1639 513 555
institution Open Polar
collection The Royal Society
op_collection_id crroyalsociety
language English
description A sound speed profile which increases monotonically with depth below the ocean surface is upward-refractive, acting as a duct in which sound may be transmitted to long ranges with little attenuation. A well-known example is the mixed layer, in which the temperature is uniform and the sound speed approximately scales with the hydrostatic pressure, increasing linearly with depth. The depth of the mixed layer depends on surface conditions, but is of the order of 100 m. Deeper channels are found in ice-covered polar waters, where the temperature and sound speed profiles both show a minimum at the surface. A typical surface duct in the Arctic Ocean may extend to depths of 1000 m or more and is capable of supporting very-low-frequency (VLF) (1-50 Hz) acoustic transmissions with no bottom interactions. On a depth scale that is smaller by several orders of magnitude, wave-breaking events create a bubbly layer one or two metres thick below the sea surface, with the highest concentration of bubbles, and correspondingly the lowest sound speed, at the surface. The bubble layer acts as a waveguide for sound in the audio frequency range, above 2 kHz, although transmission may be severely attenuated due to absorption and scattering by the bubbles, as well as by the irregular geometry of the sea surface and the bubble clouds. Most ocean-surface waveguides can be accurately represented by an inverse-square sound speed profile, which may be monotonic increasing (upward refracting) or decreasing (downward refracting) with depth, and whose detailed shape is governed by just three parameters. An analysis of the sound field below the sea surface in the presence of such a profile shows that it consists of a near-field component, given by a branch-line integral, plus a sum of uncoupled normal modes representing the trapped radiation which propagates to longer ranges. The modal contribution is identically zero in the case of the downward refracting profiles. The properties of the modes emerge from a straightforward theoretical ...
format Article in Journal/Newspaper
title On acoustic transmission in ocean-surface waveguides
spellingShingle On acoustic transmission in ocean-surface waveguides
title_short On acoustic transmission in ocean-surface waveguides
title_full On acoustic transmission in ocean-surface waveguides
title_fullStr On acoustic transmission in ocean-surface waveguides
title_full_unstemmed On acoustic transmission in ocean-surface waveguides
title_sort on acoustic transmission in ocean-surface waveguides
publisher The Royal Society
publishDate 1991
url http://dx.doi.org/10.1098/rsta.1991.0059
https://royalsocietypublishing.org/doi/pdf/10.1098/rsta.1991.0059
genre Arctic Ocean
genre_facet Arctic Ocean
op_source Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences
volume 335, issue 1639, page 513-555
ISSN 0962-8428 2054-0299
op_rights https://royalsociety.org/journals/ethics-policies/data-sharing-mining/
op_doi https://doi.org/10.1098/rsta.1991.0059
container_title Philosophical Transactions of the Royal Society of London. Series A: Physical and Engineering Sciences
container_volume 335
container_issue 1639
container_start_page 513
op_container_end_page 555
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