Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific

Abstract The northward shrinkage of the North Pacific western subarctic gyre (WSAG) in the early 2000s is associated with a sea surface height (SSH) elevation and is correlated to sea surface wind stress change. By using a Rossby wave model forced by wind stress, which computes the component variati...

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Main Authors: Akira Nagano, Masahide Wakita
Format: Article
Language:English
Published: SpringerOpen 2019-08-01
Series:Progress in Earth and Planetary Science
Subjects:
SSH
Online Access:http://link.springer.com/article/10.1186/s40645-019-0303-0
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spelling doaj-74fbbad1eaf24188b9536d246ee84cda2020-11-25T03:41:18ZengSpringerOpenProgress in Earth and Planetary Science2197-42842019-08-016112610.1186/s40645-019-0303-0Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North PacificAkira Nagano0Masahide Wakita1Research Institute for Global Change, Japan Agency for Marine-Earth Science and Technology (JAMSTEC)Mutsu Institute for Oceanography, Japan Agency for Marine-Earth Science and Technology (JAMSTEC)Abstract The northward shrinkage of the North Pacific western subarctic gyre (WSAG) in the early 2000s is associated with a sea surface height (SSH) elevation and is correlated to sea surface wind stress change. By using a Rossby wave model forced by wind stress, which computes the component variations due to the barotropic and first to fourth baroclinic modes, we estimated decadal changes in SSH and main pycnocline depth in the subpolar region. Realistic decadal SSH elevation and deepening of the main pycnocline depth associated with the northward shrinkage of the western subarctic gyre from the late 1990s to the mid-2000s were reproduced by the model. The sea surface elevation was caused primarily by the barotropic Rossby wave response to the relaxation of the Ekman suction due to the attenuation of the Aleutian Low by frequent La Niña occurrences after the late 1990s in addition to the long-term weakening of the westerly wind. The northward shrinkage of the WSAG was found to be associated with the intensification of an anticyclonic circulation centered around 43–44 ∘ N, 170–175 ∘ E. The westerly wind weakening deepened the main pycnocline in the western subarctic region through the baroclinic Rossby wave mode response to the wind stress change, which mostly accounts the equivalent halocline deepening at station K2 (47 ∘ N, 160 ∘ E). While the first baroclinic mode variation of the water density significantly attenuates during propagation, the higher mode variations, particularly the second and third mode variations, are locally excited through a quasi-resonant amplification mechanism and have profound impacts on the depth of the upper main pycnocline.http://link.springer.com/article/10.1186/s40645-019-0303-0North Pacific western subarctic gyreAleutian LowSSHBarotropic and baroclinic Rossby wavesWind stress
collection DOAJ
language English
format Article
sources DOAJ
author Akira Nagano
Masahide Wakita
spellingShingle Akira Nagano
Masahide Wakita
Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific
Progress in Earth and Planetary Science
North Pacific western subarctic gyre
Aleutian Low
SSH
Barotropic and baroclinic Rossby waves
Wind stress
author_facet Akira Nagano
Masahide Wakita
author_sort Akira Nagano
title Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific
title_short Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific
title_full Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific
title_fullStr Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific
title_full_unstemmed Wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic North Pacific
title_sort wind-driven decadal sea surface height and main pycnocline depth changes in the western subarctic north pacific
publisher SpringerOpen
series Progress in Earth and Planetary Science
issn 2197-4284
publishDate 2019-08-01
description Abstract The northward shrinkage of the North Pacific western subarctic gyre (WSAG) in the early 2000s is associated with a sea surface height (SSH) elevation and is correlated to sea surface wind stress change. By using a Rossby wave model forced by wind stress, which computes the component variations due to the barotropic and first to fourth baroclinic modes, we estimated decadal changes in SSH and main pycnocline depth in the subpolar region. Realistic decadal SSH elevation and deepening of the main pycnocline depth associated with the northward shrinkage of the western subarctic gyre from the late 1990s to the mid-2000s were reproduced by the model. The sea surface elevation was caused primarily by the barotropic Rossby wave response to the relaxation of the Ekman suction due to the attenuation of the Aleutian Low by frequent La Niña occurrences after the late 1990s in addition to the long-term weakening of the westerly wind. The northward shrinkage of the WSAG was found to be associated with the intensification of an anticyclonic circulation centered around 43–44 ∘ N, 170–175 ∘ E. The westerly wind weakening deepened the main pycnocline in the western subarctic region through the baroclinic Rossby wave mode response to the wind stress change, which mostly accounts the equivalent halocline deepening at station K2 (47 ∘ N, 160 ∘ E). While the first baroclinic mode variation of the water density significantly attenuates during propagation, the higher mode variations, particularly the second and third mode variations, are locally excited through a quasi-resonant amplification mechanism and have profound impacts on the depth of the upper main pycnocline.
topic North Pacific western subarctic gyre
Aleutian Low
SSH
Barotropic and baroclinic Rossby waves
Wind stress
url http://link.springer.com/article/10.1186/s40645-019-0303-0
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