Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation

A primitive equation model [Geophysical Fluid Dynamics Laboratory's (GFDL's) MOM 2] with one degree horizontal resolution is used to simulate the seasonal cycle of frontogenesis in the subarctic frontal zone (SAFZ) and the subtropical frontal zone (STFZ) of the North Pacific Ocean. The SAF...

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Bibliographic Details
Main Authors: Dinniman, Michael S., Rienecker, Michele M.
Format: Article in Journal/Newspaper
Language:unknown
Published: ODU Digital Commons 1999
Subjects:
Subtropical front
Subtropical mode water
Western Pacific Ocean
Variability
Temperature
Circulation
Salinity
Wind
Climate
Meteorology
Oceanography
Pacific
Subarctic
Online Access:https://digitalcommons.odu.edu/ccpo_pubs/80
https://digitalcommons.odu.edu/cgi/viewcontent.cgi?article=1100&context=ccpo_pubs
id ftolddominionuni:oai:digitalcommons.odu.edu:ccpo_pubs-1100
record_format openpolar
spelling ftolddominionuni:oai:digitalcommons.odu.edu:ccpo_pubs-1100 2023-05-15T18:28:19+02:00 Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation Dinniman, Michael S. Rienecker, Michele M. 1999-01-01T08:00:00Z application/pdf https://digitalcommons.odu.edu/ccpo_pubs/80 https://digitalcommons.odu.edu/cgi/viewcontent.cgi?article=1100&context=ccpo_pubs unknown ODU Digital Commons https://digitalcommons.odu.edu/ccpo_pubs/80 https://digitalcommons.odu.edu/cgi/viewcontent.cgi?article=1100&context=ccpo_pubs CCPO Publications Subtropical front Subtropical mode water Western Pacific Ocean Variability Temperature Circulation Salinity Wind Climate Meteorology Oceanography article 1999 ftolddominionuni 2021-03-02T18:08:05Z A primitive equation model [Geophysical Fluid Dynamics Laboratory's (GFDL's) MOM 2] with one degree horizontal resolution is used to simulate the seasonal cycle of frontogenesis in the subarctic frontal zone (SAFZ) and the subtropical frontal zone (STFZ) of the North Pacific Ocean. The SAFZ in the model contains deep (greater than 500 m in some places) regions with seasonally varying high gradients in temperature and salinity. The gradients generally weaken toward the east. The STFZ consists of a relatively shallow (less than 200 m in most places) region of high gradient in temperature that disappears in the summer/fall. The high gradient in salinity in the STFZ maintains its strength year round and extends across almost the entire basin. The model simulates the location and intensity of the frontal zones in good agreement with climatological observations: generally to within two degrees of latitude and usually at the same or slightly stronger intensity. The seasonal cycle of the frontal zones also marches observations well, although the subarctic front is stronger than observed in winter and spring. The model balances are examined to identify the dominant frontogenetic processes. The seasonal cycle of temperature frontogenesis in the surface level of the model is governed by both the convergence of the wind-driven Ekman transport and differential heating/cooling. In the STFZ, the surface Ekman convergence is frontogenetic throughout the year as opposed to surface heating, which is frontogenetic during winter and strongly frontolytic during late spring and summer. The subarctic front at 40 degrees N in the central Pacific (not the maximum wintertime gradient in the model, but its location in summer and the location where variability is in best agreement with the observations) undergoes frontogenesis during spring and summer due to surface Ekman convergence and differential horizontal shear. The frontolysis during winter is due to the joint influence of differential heat flux and vertical convection in opposition to frontogenetic Ekman convergence. The seasonal cycle of salinity frontogenesis in the surface level is governed by Ekman convergence, differential surface freshwater flux, and differential vertical convection (mixing). For salinity, the differential convection is primarily forced by Ekman convergence and differential cooling, thereby linking the salinity and temperature frontogenesis/frontolysis. Below the surface level, the seasonal frontogenesis/frontolysis is only significant in the western and central SAFZ where ii is due primarily to differential mixing (mostly in winter and early spring) with contributions from convergence and shearing advection during fall and winter. The shearing advection in the model western SAFZ is likely a result of the Kuroshio overshooting its observed separation latitude. The model's vertical mixing through convective adjustment is found to be very important in controlling much of the frontogenesis/frontolysis. Thus, the seasonal cycle of the surface frontal variability depends strongly on the subsurface structure. Article in Journal/Newspaper Subarctic Old Dominion University: ODU Digital Commons Pacific
institution Open Polar
collection Old Dominion University: ODU Digital Commons
op_collection_id ftolddominionuni
language unknown
topic Subtropical front
Subtropical mode water
Western Pacific Ocean
Variability
Temperature
Circulation
Salinity
Wind
Climate
Meteorology
Oceanography
spellingShingle Subtropical front
Subtropical mode water
Western Pacific Ocean
Variability
Temperature
Circulation
Salinity
Wind
Climate
Meteorology
Oceanography
Dinniman, Michael S.
Rienecker, Michele M.
Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation
topic_facet Subtropical front
Subtropical mode water
Western Pacific Ocean
Variability
Temperature
Circulation
Salinity
Wind
Climate
Meteorology
Oceanography
description A primitive equation model [Geophysical Fluid Dynamics Laboratory's (GFDL's) MOM 2] with one degree horizontal resolution is used to simulate the seasonal cycle of frontogenesis in the subarctic frontal zone (SAFZ) and the subtropical frontal zone (STFZ) of the North Pacific Ocean. The SAFZ in the model contains deep (greater than 500 m in some places) regions with seasonally varying high gradients in temperature and salinity. The gradients generally weaken toward the east. The STFZ consists of a relatively shallow (less than 200 m in most places) region of high gradient in temperature that disappears in the summer/fall. The high gradient in salinity in the STFZ maintains its strength year round and extends across almost the entire basin. The model simulates the location and intensity of the frontal zones in good agreement with climatological observations: generally to within two degrees of latitude and usually at the same or slightly stronger intensity. The seasonal cycle of the frontal zones also marches observations well, although the subarctic front is stronger than observed in winter and spring. The model balances are examined to identify the dominant frontogenetic processes. The seasonal cycle of temperature frontogenesis in the surface level of the model is governed by both the convergence of the wind-driven Ekman transport and differential heating/cooling. In the STFZ, the surface Ekman convergence is frontogenetic throughout the year as opposed to surface heating, which is frontogenetic during winter and strongly frontolytic during late spring and summer. The subarctic front at 40 degrees N in the central Pacific (not the maximum wintertime gradient in the model, but its location in summer and the location where variability is in best agreement with the observations) undergoes frontogenesis during spring and summer due to surface Ekman convergence and differential horizontal shear. The frontolysis during winter is due to the joint influence of differential heat flux and vertical convection in opposition to frontogenetic Ekman convergence. The seasonal cycle of salinity frontogenesis in the surface level is governed by Ekman convergence, differential surface freshwater flux, and differential vertical convection (mixing). For salinity, the differential convection is primarily forced by Ekman convergence and differential cooling, thereby linking the salinity and temperature frontogenesis/frontolysis. Below the surface level, the seasonal frontogenesis/frontolysis is only significant in the western and central SAFZ where ii is due primarily to differential mixing (mostly in winter and early spring) with contributions from convergence and shearing advection during fall and winter. The shearing advection in the model western SAFZ is likely a result of the Kuroshio overshooting its observed separation latitude. The model's vertical mixing through convective adjustment is found to be very important in controlling much of the frontogenesis/frontolysis. Thus, the seasonal cycle of the surface frontal variability depends strongly on the subsurface structure.
format Article in Journal/Newspaper
author Dinniman, Michael S.
Rienecker, Michele M.
author_facet Dinniman, Michael S.
Rienecker, Michele M.
author_sort Dinniman, Michael S.
title Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation
title_short Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation
title_full Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation
title_fullStr Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation
title_full_unstemmed Frontogenesis in the North Pacific Oceanic Frontal Zones--A Numerical Simulation
title_sort frontogenesis in the north pacific oceanic frontal zones--a numerical simulation
publisher ODU Digital Commons
publishDate 1999
url https://digitalcommons.odu.edu/ccpo_pubs/80
https://digitalcommons.odu.edu/cgi/viewcontent.cgi?article=1100&context=ccpo_pubs
geographic Pacific
geographic_facet Pacific
genre Subarctic
genre_facet Subarctic
op_source CCPO Publications
op_relation https://digitalcommons.odu.edu/ccpo_pubs/80
https://digitalcommons.odu.edu/cgi/viewcontent.cgi?article=1100&context=ccpo_pubs
_version_ 1766210731696455680

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