id ftands:oai:ands.org.au::686545
record_format openpolar
institution Open Polar
collection Research Data Australia (Australian National Data Service - ANDS)
op_collection_id ftands
language unknown
topic oceans
NUTRIENTS
EARTH SCIENCE
OCEAN CHEMISTRY
CHLOROPHYLL
PIGMENTS
dms
sulphur
dimethylsulfide
chlorophyll a
AMD/AU
CEOS
AMD
ARCTIC
OCEAN &gt
ARCTIC OCEAN
SOUTHERN OCEAN
CONTINENT &gt
NORTH AMERICA &gt
GREENLAND
GEOGRAPHIC REGION &gt
POLAR
ARCTIC OCEAN &gt
BARENTS SEA
spellingShingle oceans
NUTRIENTS
EARTH SCIENCE
OCEAN CHEMISTRY
CHLOROPHYLL
PIGMENTS
dms
sulphur
dimethylsulfide
chlorophyll a
AMD/AU
CEOS
AMD
ARCTIC
OCEAN &gt
ARCTIC OCEAN
SOUTHERN OCEAN
CONTINENT &gt
NORTH AMERICA &gt
GREENLAND
GEOGRAPHIC REGION &gt
POLAR
ARCTIC OCEAN &gt
BARENTS SEA
Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
topic_facet oceans
NUTRIENTS
EARTH SCIENCE
OCEAN CHEMISTRY
CHLOROPHYLL
PIGMENTS
dms
sulphur
dimethylsulfide
chlorophyll a
AMD/AU
CEOS
AMD
ARCTIC
OCEAN &gt
ARCTIC OCEAN
SOUTHERN OCEAN
CONTINENT &gt
NORTH AMERICA &gt
GREENLAND
GEOGRAPHIC REGION &gt
POLAR
ARCTIC OCEAN &gt
BARENTS SEA
description The Dates provided in temporal coverage are approximate only, and represent the beginning and end of the 2004 - 2007 Antarctic seasons. The latitudes and longitudes provided in spatial coverage are approximate only. Metadata record for data from ASAC Project 2584 See the link below for public details on this project. The Southern Ocean plays a significant role in the biogeochemical cycling of sulphur due to high spring-summer fluxes of dimethylsulfide (DMS), particularly south of 60 degrees S. Recent DMS flux perturbation simulations have recently highlighted the key role of the SO between 50-70 degrees S in the DMS-climate feedback hypothesis [Gabric et al., 2003; Gabric et al., 2004]. This project examines the interactions and feedback between marine polar plankton and global climate through the use of biogeochemical and global climate models, and explores the sensitivity of climate to the current and future biogenic production of dimethylsulphide at polar latitudes. This was a modelling project, and as such did not collect any data of its own. Taken from the abstracts of the referenced papers: The global climate is intimately connected to changes in the polar oceans. The variability of sea ice coverage affects deep-water formations and large-scale thermohaline circulation patterns. The polar radiative budget is sensitive to sea-ice loss and consequent surface albedo changes. Aerosols and polar cloud microphysics are crucial players in the radioactive energy balance of the Arctic Ocean. The main biogenic source of sulfate aerosols to the atmosphere above remote seas is dimethylsulfide (DMS). Recent research suggests the flux of DMS to the Arctic atmosphere may change markedly under global warming. This paper describes climate data and DMS production (based on the five years from 1998 to 2002) in the region of the Barents Sea (30-35 degrees E and 70-80 degrees N). A DMS model is introduced together with an updated calibration method. A genetic algorithm is used to calibrate the chlorophyll-a (CHL) measurements (based on satellite SeaWiFS data) and DMS content (determined from cruise data collected in the Arctic). Significant interannual variation of the CHL amount leads to significant interannual variability in the observed and modelled production of DMS in the study region. Strong DMS production in 1998 could have been caused by a large amount of ice algae being released in the southern region. Forcings from a general circulation model (CSIRO Mk3) were applied to the calibrated DMS model to predict the zonal mean sea-to-air flux of DMS for contemporary and enhanced greenhouse conditions at 70-80 degrees N. It was found that significantly decreasing ice coverage, increasing sea surface temperature and decreasing mixed-layer depth could lead to annual DMS flux increases of more than 100% by the time of equivalent CO2 tripling (the year 2080). This significant perturbation in the aerosol climate could have a large impact on the regional Arctic heat budget and consequences for global warming. ############### The response of oceanic phytoplankton to climate forcing in the Arctic Ocean has attracted increasing attention due to its special geographical position and potential susceptibility to global warming. Here, we examine the relationship between satellite derived (sea-viewing wide field-of-view sensor, SeaWiFS) surface chlorophyll-a (CHL) distribution and climatic conditions in the Barents Sea (30-35 degrees E, 70-80 degrees N) for the period 1998-2002. We separately examined the regions north and south of the Polar Front (~76 degrees N). Although field data are rather limited, the satellite CHL distribution was generally consistent with cruise observations. The temporal and spatial distribution of CHL was strongly influenced by the light regime, mixed layer depth, wind speed and ice cover. Maximum CHL values were found in the marginal sea-ice zone (72-73 degrees N) and not in the ice-free region further south (70-71 degrees N). This indicates that melt-water is an important contributor to higher CHL production. The vernal phytoplankton bloom generally started in late March, reaching its peak in late April. A second, smaller CHL peak occurred regularly in late summer (September). Of the 5 years, 2002 had the highest CHL production in the southern region, likely due to earlier ice melting and stronger solar irradiance in spring and summer. ############### Arctic ecosystems and global climate are closely related. This paper studies the distributions and the coupling relationship between Chlorophyll a (Chl a) and aerosol optical thickness (AOD) in Greenland Sea (10 degrees W - 10 degrees E, 70 degrees N - 85 degrees N) during 2003-2009 using satellite ocean colour data from MODIS Aqua. The regression analysis of EViews shows that Chl a and AOD are correlated with a time lag. Based on the lag of Chl a and AOD, co-integration inquiry finds that there is co-integration between them, which means that they will have a long-term equilibrium relationship. In general, Chl a starts from March, and gradually increases to a peak in July. The peak of AOD is usually in May, 11 weeks before Chl a. After shifting the time lag, the correlation between Chl a and AOD is 0.98 in the spring in 80 degrees N - 85 degrees N. Apart from the year of 2005, when Chl a and AOD had no time lag, the other years' intervals increased about 6 weeks within the 7 years. The peaks of AOD shifted one and a half months ahead, while Chl a also shifted about two months ahead. In northern part (75 degrees N - 85 degrees N), Chl a and AOD were much higher in the summer and autumn of 2009 than those in other years. The reason could be the much larger ice melting and higher AOD. The results indicate that the global warming has significant impact on the ecosystem in the Arctic Ocean.
author2 AADC (originator)
AU/AADC > Australian Antarctic Data Centre, Australia (resourceProvider)
format Dataset
title Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
title_short Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
title_full Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
title_fullStr Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
title_full_unstemmed Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
title_sort biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes
publisher Australian Ocean Data Network
url https://researchdata.ands.org.au/biogeochemical-modelling-feedback-polar-latitudes/686545
https://data.aad.gov.au/metadata/records/ASAC_2584
https://secure3.aad.gov.au/proms/public/projects/report_project_public.cfm?project_no=2584
http://data.aad.gov.au/aadc/portal/download_file.cfm?file_id=3355
http://data.aad.gov.au/aadc/metadata/citation.cfm?entry_id=ASAC_2584
op_coverage Spatial: northlimit=-50.0; southlimit=-70.0; westlimit=-180.0; eastLimit=180.0
Spatial: northlimit=85.0; southlimit=70.0; westlimit=-10.0; eastLimit=35.0
Temporal: From 2004-10-01 to 2007-03-31
long_lat ENVELOPE(-180.0,180.0,-50.0,-70.0)
ENVELOPE(-10.0,35.0,85.0,70.0)
geographic Antarctic
Arctic
Arctic Ocean
Barents Sea
Greenland
Southern Ocean
geographic_facet Antarctic
Arctic
Arctic Ocean
Barents Sea
Greenland
Southern Ocean
genre albedo
Antarc*
Antarctic
Arctic
Arctic Ocean
Barents Sea
Global warming
Greenland
Greenland Sea
ice algae
Phytoplankton
Sea ice
Southern Ocean
genre_facet albedo
Antarc*
Antarctic
Arctic
Arctic Ocean
Barents Sea
Global warming
Greenland
Greenland Sea
ice algae
Phytoplankton
Sea ice
Southern Ocean
op_source https://data.aad.gov.au
op_relation https://researchdata.ands.org.au/biogeochemical-modelling-feedback-polar-latitudes/686545
773123fa-5a60-4099-b051-a517b2c956f6
https://data.aad.gov.au/metadata/records/ASAC_2584
https://secure3.aad.gov.au/proms/public/projects/report_project_public.cfm?project_no=2584
http://data.aad.gov.au/aadc/portal/download_file.cfm?file_id=3355
http://data.aad.gov.au/aadc/metadata/citation.cfm?entry_id=ASAC_2584
_version_ 1766249516884819968
spelling ftands:oai:ands.org.au::686545 2023-05-15T13:11:55+02:00 Biogeochemical modelling of the feedback between ocean biota and climate at polar latitudes AADC (originator) AU/AADC > Australian Antarctic Data Centre, Australia (resourceProvider) Spatial: northlimit=-50.0; southlimit=-70.0; westlimit=-180.0; eastLimit=180.0 Spatial: northlimit=85.0; southlimit=70.0; westlimit=-10.0; eastLimit=35.0 Temporal: From 2004-10-01 to 2007-03-31 https://researchdata.ands.org.au/biogeochemical-modelling-feedback-polar-latitudes/686545 https://data.aad.gov.au/metadata/records/ASAC_2584 https://secure3.aad.gov.au/proms/public/projects/report_project_public.cfm?project_no=2584 http://data.aad.gov.au/aadc/portal/download_file.cfm?file_id=3355 http://data.aad.gov.au/aadc/metadata/citation.cfm?entry_id=ASAC_2584 unknown Australian Ocean Data Network https://researchdata.ands.org.au/biogeochemical-modelling-feedback-polar-latitudes/686545 773123fa-5a60-4099-b051-a517b2c956f6 https://data.aad.gov.au/metadata/records/ASAC_2584 https://secure3.aad.gov.au/proms/public/projects/report_project_public.cfm?project_no=2584 http://data.aad.gov.au/aadc/portal/download_file.cfm?file_id=3355 http://data.aad.gov.au/aadc/metadata/citation.cfm?entry_id=ASAC_2584 https://data.aad.gov.au oceans NUTRIENTS EARTH SCIENCE OCEAN CHEMISTRY CHLOROPHYLL PIGMENTS dms sulphur dimethylsulfide chlorophyll a AMD/AU CEOS AMD ARCTIC OCEAN &gt ARCTIC OCEAN SOUTHERN OCEAN CONTINENT &gt NORTH AMERICA &gt GREENLAND GEOGRAPHIC REGION &gt POLAR ARCTIC OCEAN &gt BARENTS SEA dataset ftands 2020-01-05T21:07:36Z The Dates provided in temporal coverage are approximate only, and represent the beginning and end of the 2004 - 2007 Antarctic seasons. The latitudes and longitudes provided in spatial coverage are approximate only. Metadata record for data from ASAC Project 2584 See the link below for public details on this project. The Southern Ocean plays a significant role in the biogeochemical cycling of sulphur due to high spring-summer fluxes of dimethylsulfide (DMS), particularly south of 60 degrees S. Recent DMS flux perturbation simulations have recently highlighted the key role of the SO between 50-70 degrees S in the DMS-climate feedback hypothesis [Gabric et al., 2003; Gabric et al., 2004]. This project examines the interactions and feedback between marine polar plankton and global climate through the use of biogeochemical and global climate models, and explores the sensitivity of climate to the current and future biogenic production of dimethylsulphide at polar latitudes. This was a modelling project, and as such did not collect any data of its own. Taken from the abstracts of the referenced papers: The global climate is intimately connected to changes in the polar oceans. The variability of sea ice coverage affects deep-water formations and large-scale thermohaline circulation patterns. The polar radiative budget is sensitive to sea-ice loss and consequent surface albedo changes. Aerosols and polar cloud microphysics are crucial players in the radioactive energy balance of the Arctic Ocean. The main biogenic source of sulfate aerosols to the atmosphere above remote seas is dimethylsulfide (DMS). Recent research suggests the flux of DMS to the Arctic atmosphere may change markedly under global warming. This paper describes climate data and DMS production (based on the five years from 1998 to 2002) in the region of the Barents Sea (30-35 degrees E and 70-80 degrees N). A DMS model is introduced together with an updated calibration method. A genetic algorithm is used to calibrate the chlorophyll-a (CHL) measurements (based on satellite SeaWiFS data) and DMS content (determined from cruise data collected in the Arctic). Significant interannual variation of the CHL amount leads to significant interannual variability in the observed and modelled production of DMS in the study region. Strong DMS production in 1998 could have been caused by a large amount of ice algae being released in the southern region. Forcings from a general circulation model (CSIRO Mk3) were applied to the calibrated DMS model to predict the zonal mean sea-to-air flux of DMS for contemporary and enhanced greenhouse conditions at 70-80 degrees N. It was found that significantly decreasing ice coverage, increasing sea surface temperature and decreasing mixed-layer depth could lead to annual DMS flux increases of more than 100% by the time of equivalent CO2 tripling (the year 2080). This significant perturbation in the aerosol climate could have a large impact on the regional Arctic heat budget and consequences for global warming. ############### The response of oceanic phytoplankton to climate forcing in the Arctic Ocean has attracted increasing attention due to its special geographical position and potential susceptibility to global warming. Here, we examine the relationship between satellite derived (sea-viewing wide field-of-view sensor, SeaWiFS) surface chlorophyll-a (CHL) distribution and climatic conditions in the Barents Sea (30-35 degrees E, 70-80 degrees N) for the period 1998-2002. We separately examined the regions north and south of the Polar Front (~76 degrees N). Although field data are rather limited, the satellite CHL distribution was generally consistent with cruise observations. The temporal and spatial distribution of CHL was strongly influenced by the light regime, mixed layer depth, wind speed and ice cover. Maximum CHL values were found in the marginal sea-ice zone (72-73 degrees N) and not in the ice-free region further south (70-71 degrees N). This indicates that melt-water is an important contributor to higher CHL production. The vernal phytoplankton bloom generally started in late March, reaching its peak in late April. A second, smaller CHL peak occurred regularly in late summer (September). Of the 5 years, 2002 had the highest CHL production in the southern region, likely due to earlier ice melting and stronger solar irradiance in spring and summer. ############### Arctic ecosystems and global climate are closely related. This paper studies the distributions and the coupling relationship between Chlorophyll a (Chl a) and aerosol optical thickness (AOD) in Greenland Sea (10 degrees W - 10 degrees E, 70 degrees N - 85 degrees N) during 2003-2009 using satellite ocean colour data from MODIS Aqua. The regression analysis of EViews shows that Chl a and AOD are correlated with a time lag. Based on the lag of Chl a and AOD, co-integration inquiry finds that there is co-integration between them, which means that they will have a long-term equilibrium relationship. In general, Chl a starts from March, and gradually increases to a peak in July. The peak of AOD is usually in May, 11 weeks before Chl a. After shifting the time lag, the correlation between Chl a and AOD is 0.98 in the spring in 80 degrees N - 85 degrees N. Apart from the year of 2005, when Chl a and AOD had no time lag, the other years' intervals increased about 6 weeks within the 7 years. The peaks of AOD shifted one and a half months ahead, while Chl a also shifted about two months ahead. In northern part (75 degrees N - 85 degrees N), Chl a and AOD were much higher in the summer and autumn of 2009 than those in other years. The reason could be the much larger ice melting and higher AOD. The results indicate that the global warming has significant impact on the ecosystem in the Arctic Ocean. Dataset albedo Antarc* Antarctic Arctic Arctic Ocean Barents Sea Global warming Greenland Greenland Sea ice algae Phytoplankton Sea ice Southern Ocean Research Data Australia (Australian National Data Service - ANDS) Antarctic Arctic Arctic Ocean Barents Sea Greenland Southern Ocean ENVELOPE(-180.0,180.0,-50.0,-70.0) ENVELOPE(-10.0,35.0,85.0,70.0)