Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence

The South-Atlantic Patagonian shelf is the largest chlorophyll-a (Chl-a) hot spot in Southern Ocean color images. While a persistent 1500 km long band of high Chl-a along the shelf-break front (SBF) is indicative of upwelling, the mechanisms that drive it are not entirely known. Along-front wind osc...

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Autor principal: Romero, Silvia Inés
Publicado: 2017
Materias:
along-front winds
chlorophyll-a
Patagonian shelf
shelf-break front upwelling
shelf-slope exchange
wind modulation
Ekman transport
frontal feature
isopycnal layer
shelf break front
slope dynamics
storm
upwelling
western boundary current
wind direction
wind forcing
Atlantic Ocean
Patagonia
Patagonian Shelf
Southern Ocean
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_21699275_v122_n3_p2401_Carranza
http://hdl.handle.net/20.500.12110/paper_21699275_v122_n3_p2401_Carranza
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_21699275_v122_n3_p2401_Carranza
record_format dspace
spelling paper:paper_21699275_v122_n3_p2401_Carranza2025-07-30T19:10:17Z Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence Romero, Silvia Inés along-front winds chlorophyll-a Patagonian shelf shelf-break front upwelling shelf-slope exchange wind modulation Ekman transport frontal feature isopycnal layer shelf break front slope dynamics storm upwelling western boundary current wind direction wind forcing Atlantic Ocean Patagonia Patagonian Shelf Southern Ocean The South-Atlantic Patagonian shelf is the largest chlorophyll-a (Chl-a) hot spot in Southern Ocean color images. While a persistent 1500 km long band of high Chl-a along the shelf-break front (SBF) is indicative of upwelling, the mechanisms that drive it are not entirely known. Along-front wind oscillations can enhance upwelling and provide a nutrient pumping mechanism at shelf-break fronts of western boundary currents. Here we assess wind-induced upwelling at the SBF off Patagonia from daily satellite Chl-a and winds, historical hydrographic observations, cross-shelf Chl-a fluorescence transects from two cruises, and in situ winds and water column structure from a mooring site. Satellite Chl-a composites segregated by along-front wind direction indicate that surface Chl-a is enhanced at the SBF with southerly winds and suppressed with northerly winds. Northerly winds also result in enhanced Chl-a further offshore (∼25–50 km). Synoptic transects as well as mean hydrographic sections segregated by along-front winds show isopycnals tilted upward for southerly winds. Spring observations from the mooring also suggest that southerly winds destratify the water column and northerly winds restratify, in agreement with Ekman transport interacting with the front. Moreover, changes in water column temperature lag along-front wind forcing by 2–4 days. Our results suggest that oscillations in along-front winds, on timescales typical of atmospheric storms (2–10 days), can significantly modulate the upwelling and Chl-a concentrations at the SBF off Patagonia, revealing the importance of wind-induced upwelling for shelf-slope exchange at shelf-break fronts of western boundary currents. © 2017. American Geophysical Union. All Rights Reserved. Fil:Romero, S.I. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2017 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_21699275_v122_n3_p2401_Carranza http://hdl.handle.net/20.500.12110/paper_21699275_v122_n3_p2401_Carranza
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic along-front winds
chlorophyll-a
Patagonian shelf
shelf-break front upwelling
shelf-slope exchange
wind modulation
Ekman transport
frontal feature
isopycnal layer
shelf break front
slope dynamics
storm
upwelling
western boundary current
wind direction
wind forcing
Atlantic Ocean
Patagonia
Patagonian Shelf
Southern Ocean
spellingShingle along-front winds
chlorophyll-a
Patagonian shelf
shelf-break front upwelling
shelf-slope exchange
wind modulation
Ekman transport
frontal feature
isopycnal layer
shelf break front
slope dynamics
storm
upwelling
western boundary current
wind direction
wind forcing
Atlantic Ocean
Patagonia
Patagonian Shelf
Southern Ocean
Romero, Silvia Inés
Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence
topic_facet along-front winds
chlorophyll-a
Patagonian shelf
shelf-break front upwelling
shelf-slope exchange
wind modulation
Ekman transport
frontal feature
isopycnal layer
shelf break front
slope dynamics
storm
upwelling
western boundary current
wind direction
wind forcing
Atlantic Ocean
Patagonia
Patagonian Shelf
Southern Ocean
description The South-Atlantic Patagonian shelf is the largest chlorophyll-a (Chl-a) hot spot in Southern Ocean color images. While a persistent 1500 km long band of high Chl-a along the shelf-break front (SBF) is indicative of upwelling, the mechanisms that drive it are not entirely known. Along-front wind oscillations can enhance upwelling and provide a nutrient pumping mechanism at shelf-break fronts of western boundary currents. Here we assess wind-induced upwelling at the SBF off Patagonia from daily satellite Chl-a and winds, historical hydrographic observations, cross-shelf Chl-a fluorescence transects from two cruises, and in situ winds and water column structure from a mooring site. Satellite Chl-a composites segregated by along-front wind direction indicate that surface Chl-a is enhanced at the SBF with southerly winds and suppressed with northerly winds. Northerly winds also result in enhanced Chl-a further offshore (∼25–50 km). Synoptic transects as well as mean hydrographic sections segregated by along-front winds show isopycnals tilted upward for southerly winds. Spring observations from the mooring also suggest that southerly winds destratify the water column and northerly winds restratify, in agreement with Ekman transport interacting with the front. Moreover, changes in water column temperature lag along-front wind forcing by 2–4 days. Our results suggest that oscillations in along-front winds, on timescales typical of atmospheric storms (2–10 days), can significantly modulate the upwelling and Chl-a concentrations at the SBF off Patagonia, revealing the importance of wind-induced upwelling for shelf-slope exchange at shelf-break fronts of western boundary currents. © 2017. American Geophysical Union. All Rights Reserved.
author Romero, Silvia Inés
author_facet Romero, Silvia Inés
author_sort Romero, Silvia Inés
title Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence
title_short Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence
title_full Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence
title_fullStr Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence
title_full_unstemmed Wind modulation of upwelling at the shelf-break front off Patagonia: Observational evidence
title_sort wind modulation of upwelling at the shelf-break front off patagonia: observational evidence
publishDate 2017
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_21699275_v122_n3_p2401_Carranza
http://hdl.handle.net/20.500.12110/paper_21699275_v122_n3_p2401_Carranza
work_keys_str_mv AT romerosilviaines windmodulationofupwellingattheshelfbreakfrontoffpatagoniaobservationalevidence
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