Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.

The Ross Sea is vulnerable to Ocean Acidification (OA) due to its relatively low total alkalinity and because of increased CO2 solubility in cold water. OA induced decreases in the saturation state (Ω) for calcite and aragonite have potentially serious consequences for Antarctic food webs. Throughou...

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Main Authors: P. Rivaro, C. Ianni, L. Langone, F. Giglio, G. Aulicino, Y. Cotroneo, M. Saggiomo, O. Mangoni
Other Authors: Rivaro, P., Ianni, C., Langone, L., Giglio, F., Aulicino, G., Cotroneo, Y., Saggiomo, M., Mangoni, O.
Format: Conference Object
Language:English
Published: 2016
Subjects:
Antarctic
Ross Sea
Antarc*
Ocean acidification
Online Access:http://hdl.handle.net/11567/913135
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record_format openpolar
spelling ftunivgenova:oai:iris.unige.it:11567/913135 2024-01-28T10:00:59+01:00 Ocean acidification state in the Ross Sea surface waters: physical and biological forcing. P. Rivaro C. Ianni L. Langone F. Giglio G. Aulicino Y. Cotroneo M. Saggiomo O. Mangoni Rivaro, P. Ianni, C. Langone, L. Giglio, F. Aulicino, G. Cotroneo, Y. Saggiomo, M. Mangoni, O. 2016 ELETTRONICO http://hdl.handle.net/11567/913135 eng eng ispartofbook:WG-EMM - Symposium on Ross Sea Ecosystem (Bologna, Italy, Wednesday 13th July 2016) WG-EMM - Symposium on Ross Sea Ecosystem firstpage:4 lastpage:4 numberofpages:1 http://hdl.handle.net/11567/913135 info:eu-repo/semantics/conferenceObject 2016 ftunivgenova 2024-01-03T17:57:09Z The Ross Sea is vulnerable to Ocean Acidification (OA) due to its relatively low total alkalinity and because of increased CO2 solubility in cold water. OA induced decreases in the saturation state (Ω) for calcite and aragonite have potentially serious consequences for Antarctic food webs. Throughout the ocean, mesoscale processes (on spatial scales of 10-100 km and temporal ranges from hours to days) have first-order impacts on phytoplankton physiochemical controls and are critical in determining growth patterns and distribution. The circulation of the surface waters in the Ross Sea is affected by the presence of small-scale structures such as eddies, fronts and filaments, which can penetrate deep below the surface layer and hence influence the intensity of the bloom by supplying nutrients and trace elements, such as iron. Little is known about the effects of mesoscale structures on the carbonate system , but predicting future surface OA state and estimating future CO2 fluxes on a regional scale require understanding of the mesoscale processes controlling the carbonate system. To this purpose, water samples were collected in January 2014 in the framework of Ross Sea Mesoscale experiment (RoME) Project to evaluate the physical and biological forcing on the carbonate system at distance between stations of 5-10 km. Remote sensing supported the determination of the sampling strategy and helped positioning each sampling station. Total alkalinity, pH, dissolved oxygen, phytoplankton pigments and composition were investigated in combination with measurements of temperature, salinity and current speed. Total inorganic carbon, sea water CO2 partial pressure and Ω for calcite and aragonite were calculated from the measured total alkalinity and pH. In addition, continuous measurements of atmospheric CO2 concentration were completed. Different mesoscale physical features, such as fronts and eddies were observed in the investigated areas, which influenced the distribution of chemical parameters and of phytoplankton ... Conference Object Antarc* Antarctic Ocean acidification Ross Sea Università degli Studi di Genova: CINECA IRIS Antarctic Ross Sea
institution Open Polar
collection Università degli Studi di Genova: CINECA IRIS
op_collection_id ftunivgenova
language English
description The Ross Sea is vulnerable to Ocean Acidification (OA) due to its relatively low total alkalinity and because of increased CO2 solubility in cold water. OA induced decreases in the saturation state (Ω) for calcite and aragonite have potentially serious consequences for Antarctic food webs. Throughout the ocean, mesoscale processes (on spatial scales of 10-100 km and temporal ranges from hours to days) have first-order impacts on phytoplankton physiochemical controls and are critical in determining growth patterns and distribution. The circulation of the surface waters in the Ross Sea is affected by the presence of small-scale structures such as eddies, fronts and filaments, which can penetrate deep below the surface layer and hence influence the intensity of the bloom by supplying nutrients and trace elements, such as iron. Little is known about the effects of mesoscale structures on the carbonate system , but predicting future surface OA state and estimating future CO2 fluxes on a regional scale require understanding of the mesoscale processes controlling the carbonate system. To this purpose, water samples were collected in January 2014 in the framework of Ross Sea Mesoscale experiment (RoME) Project to evaluate the physical and biological forcing on the carbonate system at distance between stations of 5-10 km. Remote sensing supported the determination of the sampling strategy and helped positioning each sampling station. Total alkalinity, pH, dissolved oxygen, phytoplankton pigments and composition were investigated in combination with measurements of temperature, salinity and current speed. Total inorganic carbon, sea water CO2 partial pressure and Ω for calcite and aragonite were calculated from the measured total alkalinity and pH. In addition, continuous measurements of atmospheric CO2 concentration were completed. Different mesoscale physical features, such as fronts and eddies were observed in the investigated areas, which influenced the distribution of chemical parameters and of phytoplankton ...
author2 Rivaro, P.
Ianni, C.
Langone, L.
Giglio, F.
Aulicino, G.
Cotroneo, Y.
Saggiomo, M.
Mangoni, O.
format Conference Object
author P. Rivaro
C. Ianni
L. Langone
F. Giglio
G. Aulicino
Y. Cotroneo
M. Saggiomo
O. Mangoni
spellingShingle P. Rivaro
C. Ianni
L. Langone
F. Giglio
G. Aulicino
Y. Cotroneo
M. Saggiomo
O. Mangoni
Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.
author_facet P. Rivaro
C. Ianni
L. Langone
F. Giglio
G. Aulicino
Y. Cotroneo
M. Saggiomo
O. Mangoni
author_sort P. Rivaro
title Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.
title_short Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.
title_full Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.
title_fullStr Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.
title_full_unstemmed Ocean acidification state in the Ross Sea surface waters: physical and biological forcing.
title_sort ocean acidification state in the ross sea surface waters: physical and biological forcing.
publishDate 2016
url http://hdl.handle.net/11567/913135
geographic Antarctic
Ross Sea
geographic_facet Antarctic
Ross Sea
genre Antarc*
Antarctic
Ocean acidification
Ross Sea
genre_facet Antarc*
Antarctic
Ocean acidification
Ross Sea
op_relation ispartofbook:WG-EMM - Symposium on Ross Sea Ecosystem (Bologna, Italy, Wednesday 13th July 2016)
WG-EMM - Symposium on Ross Sea Ecosystem
firstpage:4
lastpage:4
numberofpages:1
http://hdl.handle.net/11567/913135
_version_ 1789325641379741696

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