Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade

Active-source marine seismic reflection records have been used to construct acoustic images of oceanic thermohaline structure. In the water column, acoustic boundaries are produced by variations in temperature and, to a lesser extent, salinity. Acoustic waves generated by an array of airguns suspend...

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Bibliographic Details
Main Author: Dickinson, Nicholas Alexander
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: University of Cambridge 2019
Subjects:
Seismic reflection profiling
Oceanic mixing
Physical oceanography
Munk
Nordic Seas
Online Access:https://www.repository.cam.ac.uk/handle/1810/293721
https://doi.org/10.17863/CAM.40834
id ftunivcam:oai:www.repository.cam.ac.uk:1810/293721
record_format openpolar
institution Open Polar
collection Apollo - University of Cambridge Repository
op_collection_id ftunivcam
language English
topic Seismic reflection profiling
Oceanic mixing
Physical oceanography
spellingShingle Seismic reflection profiling
Oceanic mixing
Physical oceanography
Dickinson, Nicholas Alexander
Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade
topic_facet Seismic reflection profiling
Oceanic mixing
Physical oceanography
description Active-source marine seismic reflection records have been used to construct acoustic images of oceanic thermohaline structure. In the water column, acoustic boundaries are produced by variations in temperature and, to a lesser extent, salinity. Acoustic waves generated by an array of airguns suspended behind a vessel are reflected from these boundaries and recorded by long cables of hydrophones which are towed beneath the sea surface. Careful signal processing of these records yields acoustic images of thermohaline structure with both horizontal and vertical resolutions of $O(10)$~m. In this dissertation, a three-dimensional seismic survey from the Faroe-Shetland Channel and a two-dimensional seismic survey from the Gulf of Mexico are presented and analysed. In the Faroe-Shetland Channel, 54 seismic transects were acquired over 25 days in July-August 1997. These transects were recorded sequentially, with adjacent transects separated by $\sim 0.3$~km and $\sim 1$~day. The survey thus provides time-lapse sampling of local thermohaline structure within an area of $\sim 150$~km$^2$. Processed acoustic images are dominated by a prominent band of bright reflections at depth. Calibration using nearby hydrographic measurements shows that this band corresponds to a pycnocline which separates warm near-surface waters from cold deep waters. The depth of the pycnocline varies by $\sim 350$~m over $\sim 10$~days. Acoustic reflections within the pycnocline are tilted by up to 1\textdegree \ with respect to the horizontal, suggesting currents in geostrophic balance. Temporal variations in pycnocline depth and in reflection tilt are consistent with northeastward advection of a mesoscale anticyclonic vortex. Comparison with contemporaneous satellite measurements of sea-surface temperature and sea-surface height suggests that this vortex is caused by meandering of the Continental Slope Current. These results have significant implications for our understanding of how mesoscale activity in the Faroe-Shetland Channel affects flux of heat and salt to the Nordic Seas. At finer scales, the seismic images show clearly defined internal waves. The geometry of these waves is compared with theoretical descriptions of linear and nonlinear waves in a two-layer fluid. The form of the internal wave field and of localised turbulence is investigated by spectrally analysing the vertical displacements of automatically tracked reflections. Internal wave spectra differ markedly from the open-ocean Garrett-Munk model spectrum. Diapycnal diffusivities are estimated from clear turbulent spectral subranges. Temporal variations in the form of spectra are related to changes in shear and stratification associated with passage of the mesoscale vortex. In the Gulf of Mexico, a single seismic image shows clear reflections in the uppermost $\sim 1000$~m adjacent to and overlying the continental slope. Spectral analysis of these reflections shows that the local internal wave field is accurately described by the Garrett-Munk spectrum. Diapycnal diffusivities are estimated using a semi-empirical parametrisation of internal wave energy. Comparison with diffusivities estimated from nearby hydrographic records and with previous measurements indicates that this method is robust. The analyses presented in this dissertation suggest that automated signal processing and interpretation of existing seismic reflection records has the potential to strengthen our understanding of the dynamical links between oceanic mesoscale activity, internal waves and turbulence. This project was sponsored by the Natural Environment Research Council (NERC).
format Doctoral or Postdoctoral Thesis
author Dickinson, Nicholas Alexander
author_facet Dickinson, Nicholas Alexander
author_sort Dickinson, Nicholas Alexander
title Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade
title_short Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade
title_full Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade
title_fullStr Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade
title_full_unstemmed Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade
title_sort time-lapse acoustic imaging of the oceanic energy cascade
publisher University of Cambridge
publishDate 2019
url https://www.repository.cam.ac.uk/handle/1810/293721
https://doi.org/10.17863/CAM.40834
long_lat ENVELOPE(-95.993,-95.993,55.979,55.979)
geographic Munk
geographic_facet Munk
genre Nordic Seas
genre_facet Nordic Seas
op_relation https://www.repository.cam.ac.uk/handle/1810/293721
doi:10.17863/CAM.40834
op_rights All rights reserved
https://www.rioxx.net/licenses/all-rights-reserved/
op_doi https://doi.org/10.17863/CAM.40834
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spelling ftunivcam:oai:www.repository.cam.ac.uk:1810/293721 2023-05-15T17:24:25+02:00 Time-Lapse Acoustic Imaging of the Oceanic Energy Cascade Dickinson, Nicholas Alexander 2019-06-18T14:30:46Z https://www.repository.cam.ac.uk/handle/1810/293721 https://doi.org/10.17863/CAM.40834 en eng University of Cambridge Earth Sciences Robinson https://www.repository.cam.ac.uk/handle/1810/293721 doi:10.17863/CAM.40834 All rights reserved https://www.rioxx.net/licenses/all-rights-reserved/ Seismic reflection profiling Oceanic mixing Physical oceanography Thesis Doctoral Doctor of Philosophy (PhD) PhD in Physical Oceanography 2019 ftunivcam https://doi.org/10.17863/CAM.40834 2021-04-22T22:17:01Z Active-source marine seismic reflection records have been used to construct acoustic images of oceanic thermohaline structure. In the water column, acoustic boundaries are produced by variations in temperature and, to a lesser extent, salinity. Acoustic waves generated by an array of airguns suspended behind a vessel are reflected from these boundaries and recorded by long cables of hydrophones which are towed beneath the sea surface. Careful signal processing of these records yields acoustic images of thermohaline structure with both horizontal and vertical resolutions of $O(10)$~m. In this dissertation, a three-dimensional seismic survey from the Faroe-Shetland Channel and a two-dimensional seismic survey from the Gulf of Mexico are presented and analysed. In the Faroe-Shetland Channel, 54 seismic transects were acquired over 25 days in July-August 1997. These transects were recorded sequentially, with adjacent transects separated by $\sim 0.3$~km and $\sim 1$~day. The survey thus provides time-lapse sampling of local thermohaline structure within an area of $\sim 150$~km$^2$. Processed acoustic images are dominated by a prominent band of bright reflections at depth. Calibration using nearby hydrographic measurements shows that this band corresponds to a pycnocline which separates warm near-surface waters from cold deep waters. The depth of the pycnocline varies by $\sim 350$~m over $\sim 10$~days. Acoustic reflections within the pycnocline are tilted by up to 1\textdegree \ with respect to the horizontal, suggesting currents in geostrophic balance. Temporal variations in pycnocline depth and in reflection tilt are consistent with northeastward advection of a mesoscale anticyclonic vortex. Comparison with contemporaneous satellite measurements of sea-surface temperature and sea-surface height suggests that this vortex is caused by meandering of the Continental Slope Current. These results have significant implications for our understanding of how mesoscale activity in the Faroe-Shetland Channel affects flux of heat and salt to the Nordic Seas. At finer scales, the seismic images show clearly defined internal waves. The geometry of these waves is compared with theoretical descriptions of linear and nonlinear waves in a two-layer fluid. The form of the internal wave field and of localised turbulence is investigated by spectrally analysing the vertical displacements of automatically tracked reflections. Internal wave spectra differ markedly from the open-ocean Garrett-Munk model spectrum. Diapycnal diffusivities are estimated from clear turbulent spectral subranges. Temporal variations in the form of spectra are related to changes in shear and stratification associated with passage of the mesoscale vortex. In the Gulf of Mexico, a single seismic image shows clear reflections in the uppermost $\sim 1000$~m adjacent to and overlying the continental slope. Spectral analysis of these reflections shows that the local internal wave field is accurately described by the Garrett-Munk spectrum. Diapycnal diffusivities are estimated using a semi-empirical parametrisation of internal wave energy. Comparison with diffusivities estimated from nearby hydrographic records and with previous measurements indicates that this method is robust. The analyses presented in this dissertation suggest that automated signal processing and interpretation of existing seismic reflection records has the potential to strengthen our understanding of the dynamical links between oceanic mesoscale activity, internal waves and turbulence. This project was sponsored by the Natural Environment Research Council (NERC). Doctoral or Postdoctoral Thesis Nordic Seas Apollo - University of Cambridge Repository Munk ENVELOPE(-95.993,-95.993,55.979,55.979)

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