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Observations of the space/time scales of Beaufort sea acoustic duct variability and their impact on transmission loss via the mode interaction parameter

The Beaufort duct (BD) is a subsurface sound channel in the western Arctic Ocean formed by cold Pacific Winter Water (PWW) sandwiched between warmer Pacific Summer Water (PSW) and Atlantic Water (AW). Sound waves can be trapped in this duct and travel long distances without experiencing lossy surfac...

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Bibliographic Details
Published in:The Journal of the Acoustical Society of America 2023-05, Vol.153 (5), p.2659-2676
Main Authors: Kucukosmanoglu, Murat, Colosi, John A., Worcester, Peter F., Dzieciuch, Matthew A., Sagen, Hanne, Duda, Timothy F., Zhang, Weifeng Gordon, Miller, Christopher W., Richards, Edward L.
Format: Article
Language:English
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Summary:The Beaufort duct (BD) is a subsurface sound channel in the western Arctic Ocean formed by cold Pacific Winter Water (PWW) sandwiched between warmer Pacific Summer Water (PSW) and Atlantic Water (AW). Sound waves can be trapped in this duct and travel long distances without experiencing lossy surface/ice interactions. This study analyzes BD vertical and temporal variability using moored oceanographic measurements from two yearlong acoustic transmission experiments (2016–2017 and 2019–2020). The focus is on BD normal mode propagation through observed ocean features, such as eddies and spicy intrusions, where direct numerical simulations and the mode interaction parameter (MIP) are used to quantify ducted mode coupling strength. The observations show strong PSW sound speed variability, weak variability in the PWW, and moderate variability in the AW, with typical time scales from days to weeks. For several hundreds Hertz propagation, the BD modes are relatively stable, except for rare episodes of strong sound speed perturbations. The MIP identifies a resonance condition such that the likelihood of coupling is greatest when there is significant sound speed variability in the horizontal wave number band 1 / 11 < k h < 1 / 5   k m − 1. MITgcm ocean model results are used to estimate sound speed fluctuations in this resonance regime.
ISSN:0001-4966
1520-8524
DOI:10.1121/10.0019335