ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER

Theoretical studies and numerical experiments of the subarctic front are conducted. The theoretical side of this research encompasses the determination of a stability criterion and the role friction plays as a dissipative mechanism. In the first case study, it is established that if the difference b...

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Other Authors: CAMERLENGO, ALEJANDRO LIVIO., Florida State University
Format: Text
Language:unknown
Subjects:
Physical Oceanography
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Subarctic
Online Access:http://purl.flvc.org/fsu/lib/digcoll/etd/3084892
http://fsu.digital.flvc.org/islandora/object/fsu%3A74393/datastream/TN/view/ON%20THE%20DYNAMICAL%20RESPONSE%20OF%20THE%20SUBARCTIC%20FRONT%20TO%20MOMENTUM%20TRANSFER.jpg
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spelling ftfloridastunidc:oai:fsu.digital.flvc.org:fsu_74393 2023-05-15T18:28:06+02:00 ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER CAMERLENGO, ALEJANDRO LIVIO. Florida State University 102 p. http://purl.flvc.org/fsu/lib/digcoll/etd/3084892 http://fsu.digital.flvc.org/islandora/object/fsu%3A74393/datastream/TN/view/ON%20THE%20DYNAMICAL%20RESPONSE%20OF%20THE%20SUBARCTIC%20FRONT%20TO%20MOMENTUM%20TRANSFER.jpg unknown Dissertation Abstracts International On campus use only. Physical Oceanography Text ftfloridastunidc 2020-08-10T18:41:30Z Theoretical studies and numerical experiments of the subarctic front are conducted. The theoretical side of this research encompasses the determination of a stability criterion and the role friction plays as a dissipative mechanism. In the first case study, it is established that if the difference between the phase speed of the perturbation and the mean long-front geostrophic flow is greater than a certain value, the subarctic front is stable everywhere. In the other case study, it is proved that the time scale of dissipation is sufficiently large to neglect horizontal friction. While the effect of the westerly winds causes a southward shift of the front, the effect of a negative curl shows convergence at the front. This convergence strongly favors frontogenesis. It is established that the phase speed of the first baroclinic mode is larger in a numerical model where a constant density jump between layers is employed. Thus, a smaller time scale is required to avoid the numerical instability caused by the violation of the CFL criterion. A numerical four-layer hydrodynamical model is implemented to investigate the role the atmosphere exerts on the dynamics of the subarctic front. The salient features at the wake of a strong cyclone can be summarized as follows: (i) upwelling of 20 meters of the four interfaces occurs; (ii) the water remains upwelled for several weeks; (iii) the e-folding time scale of the vertical oscillations induced by the storm's passage is of the order of 10 days; (iv) a region of relative maximum convergence is observed in the lower layers below a region of relative maximum upwelling in the upper layer; and (v) the long and cross-front velocity fields are in quadrature in time, with the cross front velocity lagging the long front velocity. With the exception of the cyclone's case, it is established that the effects of the atmospheric wind forcing are confined to the upper layer. These results are supported by oceanic observations. Finally, it is also proved that the response of the front to the atmospheric momentum transfer is independent of the initial form of the subarctic front. Source: Dissertation Abstracts International, Volume: 42-01, Section: B, page: 0121. Thesis (Ph.D.)--The Florida State University, 1981. Text Subarctic Florida State University Digital Library (FSUDL) Curl ENVELOPE(-63.071,-63.071,-70.797,-70.797)
institution Open Polar
collection Florida State University Digital Library (FSUDL)
op_collection_id ftfloridastunidc
language unknown
topic Physical Oceanography
spellingShingle Physical Oceanography
ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER
topic_facet Physical Oceanography
description Theoretical studies and numerical experiments of the subarctic front are conducted. The theoretical side of this research encompasses the determination of a stability criterion and the role friction plays as a dissipative mechanism. In the first case study, it is established that if the difference between the phase speed of the perturbation and the mean long-front geostrophic flow is greater than a certain value, the subarctic front is stable everywhere. In the other case study, it is proved that the time scale of dissipation is sufficiently large to neglect horizontal friction. While the effect of the westerly winds causes a southward shift of the front, the effect of a negative curl shows convergence at the front. This convergence strongly favors frontogenesis. It is established that the phase speed of the first baroclinic mode is larger in a numerical model where a constant density jump between layers is employed. Thus, a smaller time scale is required to avoid the numerical instability caused by the violation of the CFL criterion. A numerical four-layer hydrodynamical model is implemented to investigate the role the atmosphere exerts on the dynamics of the subarctic front. The salient features at the wake of a strong cyclone can be summarized as follows: (i) upwelling of 20 meters of the four interfaces occurs; (ii) the water remains upwelled for several weeks; (iii) the e-folding time scale of the vertical oscillations induced by the storm's passage is of the order of 10 days; (iv) a region of relative maximum convergence is observed in the lower layers below a region of relative maximum upwelling in the upper layer; and (v) the long and cross-front velocity fields are in quadrature in time, with the cross front velocity lagging the long front velocity. With the exception of the cyclone's case, it is established that the effects of the atmospheric wind forcing are confined to the upper layer. These results are supported by oceanic observations. Finally, it is also proved that the response of the front to the atmospheric momentum transfer is independent of the initial form of the subarctic front. Source: Dissertation Abstracts International, Volume: 42-01, Section: B, page: 0121. Thesis (Ph.D.)--The Florida State University, 1981.
author2 CAMERLENGO, ALEJANDRO LIVIO.
Florida State University
format Text
title ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER
title_short ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER
title_full ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER
title_fullStr ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER
title_full_unstemmed ON THE DYNAMICAL RESPONSE OF THE SUBARCTIC FRONT TO MOMENTUM TRANSFER
title_sort on the dynamical response of the subarctic front to momentum transfer
url http://purl.flvc.org/fsu/lib/digcoll/etd/3084892
http://fsu.digital.flvc.org/islandora/object/fsu%3A74393/datastream/TN/view/ON%20THE%20DYNAMICAL%20RESPONSE%20OF%20THE%20SUBARCTIC%20FRONT%20TO%20MOMENTUM%20TRANSFER.jpg
long_lat ENVELOPE(-63.071,-63.071,-70.797,-70.797)
geographic Curl
geographic_facet Curl
genre Subarctic
genre_facet Subarctic
op_relation Dissertation Abstracts International
op_rights On campus use only.
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