Microfossil and stable-isotope evidence for changes in Late Holocene palaeoproductivity and palaeoceanographic conditions in the Prydz Bay region of Antarctica
Identifieur interne : 00CD83 ( Main/Exploration ); précédent : 00CD82; suivant : 00CD84Microfossil and stable-isotope evidence for changes in Late Holocene palaeoproductivity and palaeoceanographic conditions in the Prydz Bay region of Antarctica
Auteurs : A. E. Rathburn [Australie, États-Unis] ; J.-J. Pichon [France] ; M. A. Ayress [Australie] ; P. De Deckker [Australie]Source :
- Palaeogeography, Palaeoclimatology, Palaeoecology [ 0031-0182 ] ; 1997.
Descripteurs français
- Wicri :
- topic : Antarctique, Changement climatique, Plateau continental.
English descriptors
- KwdEn :
- Abundance, Abundance maxima, Abundance patterns, Agglutinated foraminifera, Antarctic, Antarctic margin, Antarctic peninsula, Antarctic reservoir factor, Antarctic shelf, Antarctica, Antarctica spore state, Assemblage, Benthic, Benthic assemblages, Benthic foraminifera, Biogenic, Biogenic carbonate, Calcareous, Calcareous sediments, Cambridge univ, Carbonate, Central portion, Central prydz, Chaetoceros, Chaetoceros spore state, Chelnok glaciation, Cibicides, Climate change, Continental shelf, Corethron, Corethron criophilum, Correction factor, Correction factors, Criophilum, Curta, Diatom, Diatom assemblages, Diatom taxa, Diatomaceous, Diatomaceous sediments, Domack, Dominant taxa, East antarctic, East antarctica, Environmental changes, Environmental conditions, Faunal, Floral patterns, Fluctuation, Foraminifera, Foraminiferal, Foraminiferal assemblages, Fram, Fram bank, Fram bank area, Geol, Glacial, Glacier, Granite harbor, Gravity cores, Holocene, Isotope, Isotope patterns, Isotopic, Isotopic composition, Jacobs, Late holocene, Leventer, Lower portion, Mass sedimentation, Mcmurdo, Mcmurdo sound, Meltwater, Microfossil, Microfossil abundances, Modern sediments, Nitzschia, Nitzschia species, Oceanographic, Oceanographic change, Oceanographic changes, Oceanographic conditions, Open water, Open water conditions, Organic material, Ostracod, Other areas, Pachyderma, Palaeoclimatology, Palaeoecology, Palaeogeography, Phytoplankton, Planktonic, Planktonic foraminifera, Pleistocene, Primary factor, Prydz, Radiocarbon, Radiocarbon ages, Rathburn, Relative abundances, Robertson, Robertson shelf, Salinity, Sediment, Sedimentation, Sedimentation rates, Shelf, Shelf waters, Significant changes, Southern ocean, Spore, Stablizing effects, Stockwell, Surface sediments, Surficial, Surficial material, Surficial sediments, Taviani, Taxon, Time period, Total abundances, Upper water column, Upwelling, Vestfold hills, Visual evidence, Water column, Water masses, Weddell, Winnowing.
- Teeft :
- Abundance, Abundance maxima, Abundance patterns, Agglutinated foraminifera, Antarctic, Antarctic margin, Antarctic peninsula, Antarctic reservoir factor, Antarctic shelf, Antarctica, Antarctica spore state, Assemblage, Benthic, Benthic assemblages, Benthic foraminifera, Biogenic, Biogenic carbonate, Calcareous, Calcareous sediments, Cambridge univ, Carbonate, Central portion, Central prydz, Chaetoceros, Chaetoceros spore state, Chelnok glaciation, Cibicides, Climate change, Continental shelf, Corethron, Corethron criophilum, Correction factor, Correction factors, Criophilum, Curta, Diatom, Diatom assemblages, Diatom taxa, Diatomaceous, Diatomaceous sediments, Domack, Dominant taxa, East antarctic, East antarctica, Environmental changes, Environmental conditions, Faunal, Floral patterns, Fluctuation, Foraminifera, Foraminiferal, Foraminiferal assemblages, Fram, Fram bank, Fram bank area, Geol, Glacial, Glacier, Granite harbor, Gravity cores, Holocene, Isotope, Isotope patterns, Isotopic, Isotopic composition, Jacobs, Late holocene, Leventer, Lower portion, Mass sedimentation, Mcmurdo, Mcmurdo sound, Meltwater, Microfossil, Microfossil abundances, Modern sediments, Nitzschia, Nitzschia species, Oceanographic, Oceanographic change, Oceanographic changes, Oceanographic conditions, Open water, Open water conditions, Organic material, Ostracod, Other areas, Pachyderma, Palaeoclimatology, Palaeoecology, Palaeogeography, Phytoplankton, Planktonic, Planktonic foraminifera, Pleistocene, Primary factor, Prydz, Radiocarbon, Radiocarbon ages, Rathburn, Relative abundances, Robertson, Robertson shelf, Salinity, Sediment, Sedimentation, Sedimentation rates, Shelf, Shelf waters, Significant changes, Southern ocean, Spore, Stablizing effects, Stockwell, Surface sediments, Surficial, Surficial material, Surficial sediments, Taviani, Taxon, Time period, Total abundances, Upper water column, Upwelling, Vestfold hills, Visual evidence, Water column, Water masses, Weddell, Winnowing.
Abstract
Abstract: Microfaunal and microfloral data from two gravity cores, and stable-isotope results from one of these cores taken on Fram Bank near Prydz Bay, Antarctica indicate changes in sea-ice patterns and oceanographic conditions which may have been linked to regional and global climate changes that occurred over the past 8000 yr. Modern diatom assemblages indicative of ice free conditions 1–2 months of the year, and dominated by Nitzschia species became prevalent some time around 2000–2700 yr B.P. The occurrence of Chaetoceros spp. diatom spore-dominated assemblages, and increased abundances of benthic and planktonic foraminifera, ostracods, and diatoms, coupled with carbon- and oxygen-isotope changes around 2700–3400 yr B.P. strongly suggests that this area of the shelf experienced conditions conducive to increased productivity during this time period. Based on diatom assemblage associations recognized in modern environments, the upper water column of Fram Bank shelf waters was probably stratified during that time due to the presence of low-salinity melt water and a very shallow mixed layer, protected from storms, with sea-ice cover for less than 10 months per year. The close correspondence of δ13C and δ18O values from N. pachyderma (r2 = 0.74) throughout one core suggests that whatever oceanographic conditions influenced δ18O also influenced δ13C. Changes in Prydz Bay microfossil abundances and isotopes may result from alterations in circulation patterns, upwelling conditions, or sea-ice patterns which significantly affected benthic and planktonic productivity in the area. The environmental conditions indicated by older sediments in the cores are less clear, but an ice tongue may have been in place 3200–3800 yr B.P., and minor fluctuations in productivity are indicated around 6000 and 7000–7500 yr B.P. The lower 100 cm of both cores may not represent in situ deposition, but if the corrected AMS dates reflect the actual age of the sediments analyzed, microfossil and isotope data indicate that productivity, and oceanographic conditions were very variable around 8500-8600 yr B.P. The chronology adopted herein must be regarded as tentative until further study of the area has been undèrtaken.
Url:
DOI: 10.1016/S0031-0182(97)00017-5
Affiliations:
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E." last="Rathburn">A. E. Rathburn</name><affiliation wicri:level="1"><country xml:lang="fr">Australie</country><wicri:regionArea>The Australian Marine Quaternary Program, Department of Geology, The Australian National University, Canberra, A.C.T. 0200</wicri:regionArea><wicri:noRegion>A.C.T. 0200</wicri:noRegion></affiliation><affiliation wicri:level="2"><country xml:lang="fr">États-Unis</country><wicri:regionArea>c Current address: Scripps Institution of Oceanography, Marine Life Research Group, 9500 Gilman Drive, La Jolla, CA 92093-0218</wicri:regionArea><placeName><region type="state">Californie</region></placeName></affiliation></author><author><name sortKey="Pichon, J J" sort="Pichon, J J" uniqKey="Pichon J" first="J.-J." last="Pichon">J.-J. Pichon</name><affiliation wicri:level="1"><country xml:lang="fr">France</country><wicri:regionArea>Département de Géologie et Océanographié, Université de Bordeaux I, Avenue des Facultés, 33405 Talence, Cedex</wicri:regionArea><wicri:noRegion>Cedex</wicri:noRegion><wicri:noRegion>Cedex</wicri:noRegion></affiliation></author><author><name sortKey="Ayress, M A" sort="Ayress, M A" uniqKey="Ayress M" first="M. A." last="Ayress">M. A. Ayress</name><affiliation wicri:level="1"><country xml:lang="fr">Australie</country><wicri:regionArea>The Australian Marine Quaternary Program, Department of Geology, The Australian National University, Canberra, A.C.T. 0200</wicri:regionArea><wicri:noRegion>A.C.T. 0200</wicri:noRegion></affiliation></author><author><name sortKey="De Deckker, P" sort="De Deckker, P" uniqKey="De Deckker P" first="P." last="De Deckker">P. De Deckker</name><affiliation wicri:level="1"><country xml:lang="fr">Australie</country><wicri:regionArea>The Australian Marine Quaternary Program, Department of Geology, The Australian National University, Canberra, A.C.T. 0200</wicri:regionArea><wicri:noRegion>A.C.T. 0200</wicri:noRegion></affiliation></author></analytic><monogr></monogr><series><title level="j">Palaeogeography, Palaeoclimatology, Palaeoecology</title><title level="j" type="abbrev">PALAEO</title><idno type="ISSN">0031-0182</idno><imprint><publisher>ELSEVIER</publisher><date type="published" when="1997">1997</date><biblScope unit="volume">131</biblScope><biblScope unit="issue">3–4</biblScope><biblScope unit="page" from="485">485</biblScope><biblScope unit="page" to="510">510</biblScope></imprint><idno type="ISSN">0031-0182</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">0031-0182</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Abundance</term><term>Abundance maxima</term><term>Abundance patterns</term><term>Agglutinated foraminifera</term><term>Antarctic</term><term>Antarctic margin</term><term>Antarctic peninsula</term><term>Antarctic reservoir factor</term><term>Antarctic shelf</term><term>Antarctica</term><term>Antarctica spore state</term><term>Assemblage</term><term>Benthic</term><term>Benthic assemblages</term><term>Benthic foraminifera</term><term>Biogenic</term><term>Biogenic carbonate</term><term>Calcareous</term><term>Calcareous sediments</term><term>Cambridge univ</term><term>Carbonate</term><term>Central portion</term><term>Central prydz</term><term>Chaetoceros</term><term>Chaetoceros spore state</term><term>Chelnok glaciation</term><term>Cibicides</term><term>Climate change</term><term>Continental shelf</term><term>Corethron</term><term>Corethron criophilum</term><term>Correction factor</term><term>Correction factors</term><term>Criophilum</term><term>Curta</term><term>Diatom</term><term>Diatom assemblages</term><term>Diatom taxa</term><term>Diatomaceous</term><term>Diatomaceous sediments</term><term>Domack</term><term>Dominant taxa</term><term>East antarctic</term><term>East antarctica</term><term>Environmental changes</term><term>Environmental conditions</term><term>Faunal</term><term>Floral patterns</term><term>Fluctuation</term><term>Foraminifera</term><term>Foraminiferal</term><term>Foraminiferal assemblages</term><term>Fram</term><term>Fram bank</term><term>Fram bank area</term><term>Geol</term><term>Glacial</term><term>Glacier</term><term>Granite harbor</term><term>Gravity cores</term><term>Holocene</term><term>Isotope</term><term>Isotope patterns</term><term>Isotopic</term><term>Isotopic composition</term><term>Jacobs</term><term>Late holocene</term><term>Leventer</term><term>Lower portion</term><term>Mass sedimentation</term><term>Mcmurdo</term><term>Mcmurdo sound</term><term>Meltwater</term><term>Microfossil</term><term>Microfossil abundances</term><term>Modern sediments</term><term>Nitzschia</term><term>Nitzschia species</term><term>Oceanographic</term><term>Oceanographic change</term><term>Oceanographic changes</term><term>Oceanographic conditions</term><term>Open water</term><term>Open water conditions</term><term>Organic material</term><term>Ostracod</term><term>Other areas</term><term>Pachyderma</term><term>Palaeoclimatology</term><term>Palaeoecology</term><term>Palaeogeography</term><term>Phytoplankton</term><term>Planktonic</term><term>Planktonic foraminifera</term><term>Pleistocene</term><term>Primary factor</term><term>Prydz</term><term>Radiocarbon</term><term>Radiocarbon ages</term><term>Rathburn</term><term>Relative abundances</term><term>Robertson</term><term>Robertson shelf</term><term>Salinity</term><term>Sediment</term><term>Sedimentation</term><term>Sedimentation rates</term><term>Shelf</term><term>Shelf waters</term><term>Significant changes</term><term>Southern ocean</term><term>Spore</term><term>Stablizing effects</term><term>Stockwell</term><term>Surface sediments</term><term>Surficial</term><term>Surficial material</term><term>Surficial sediments</term><term>Taviani</term><term>Taxon</term><term>Time period</term><term>Total abundances</term><term>Upper water column</term><term>Upwelling</term><term>Vestfold hills</term><term>Visual evidence</term><term>Water column</term><term>Water masses</term><term>Weddell</term><term>Winnowing</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Abundance</term><term>Abundance maxima</term><term>Abundance patterns</term><term>Agglutinated foraminifera</term><term>Antarctic</term><term>Antarctic margin</term><term>Antarctic peninsula</term><term>Antarctic reservoir factor</term><term>Antarctic shelf</term><term>Antarctica</term><term>Antarctica spore state</term><term>Assemblage</term><term>Benthic</term><term>Benthic assemblages</term><term>Benthic foraminifera</term><term>Biogenic</term><term>Biogenic carbonate</term><term>Calcareous</term><term>Calcareous sediments</term><term>Cambridge univ</term><term>Carbonate</term><term>Central portion</term><term>Central prydz</term><term>Chaetoceros</term><term>Chaetoceros spore state</term><term>Chelnok glaciation</term><term>Cibicides</term><term>Climate change</term><term>Continental shelf</term><term>Corethron</term><term>Corethron criophilum</term><term>Correction factor</term><term>Correction factors</term><term>Criophilum</term><term>Curta</term><term>Diatom</term><term>Diatom assemblages</term><term>Diatom taxa</term><term>Diatomaceous</term><term>Diatomaceous sediments</term><term>Domack</term><term>Dominant taxa</term><term>East antarctic</term><term>East antarctica</term><term>Environmental changes</term><term>Environmental conditions</term><term>Faunal</term><term>Floral patterns</term><term>Fluctuation</term><term>Foraminifera</term><term>Foraminiferal</term><term>Foraminiferal assemblages</term><term>Fram</term><term>Fram bank</term><term>Fram bank area</term><term>Geol</term><term>Glacial</term><term>Glacier</term><term>Granite harbor</term><term>Gravity cores</term><term>Holocene</term><term>Isotope</term><term>Isotope patterns</term><term>Isotopic</term><term>Isotopic composition</term><term>Jacobs</term><term>Late holocene</term><term>Leventer</term><term>Lower portion</term><term>Mass sedimentation</term><term>Mcmurdo</term><term>Mcmurdo sound</term><term>Meltwater</term><term>Microfossil</term><term>Microfossil abundances</term><term>Modern sediments</term><term>Nitzschia</term><term>Nitzschia species</term><term>Oceanographic</term><term>Oceanographic change</term><term>Oceanographic changes</term><term>Oceanographic conditions</term><term>Open water</term><term>Open water conditions</term><term>Organic material</term><term>Ostracod</term><term>Other areas</term><term>Pachyderma</term><term>Palaeoclimatology</term><term>Palaeoecology</term><term>Palaeogeography</term><term>Phytoplankton</term><term>Planktonic</term><term>Planktonic foraminifera</term><term>Pleistocene</term><term>Primary factor</term><term>Prydz</term><term>Radiocarbon</term><term>Radiocarbon ages</term><term>Rathburn</term><term>Relative abundances</term><term>Robertson</term><term>Robertson shelf</term><term>Salinity</term><term>Sediment</term><term>Sedimentation</term><term>Sedimentation rates</term><term>Shelf</term><term>Shelf waters</term><term>Significant changes</term><term>Southern ocean</term><term>Spore</term><term>Stablizing effects</term><term>Stockwell</term><term>Surface sediments</term><term>Surficial</term><term>Surficial material</term><term>Surficial sediments</term><term>Taviani</term><term>Taxon</term><term>Time period</term><term>Total abundances</term><term>Upper water column</term><term>Upwelling</term><term>Vestfold hills</term><term>Visual evidence</term><term>Water column</term><term>Water masses</term><term>Weddell</term><term>Winnowing</term></keywords><keywords scheme="Wicri" type="topic" xml:lang="fr"><term>Antarctique</term><term>Changement climatique</term><term>Plateau continental</term></keywords></textClass><langUsage><language ident="en">en</language></langUsage></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Abstract: Microfaunal and microfloral data from two gravity cores, and stable-isotope results from one of these cores taken on Fram Bank near Prydz Bay, Antarctica indicate changes in sea-ice patterns and oceanographic conditions which may have been linked to regional and global climate changes that occurred over the past 8000 yr. Modern diatom assemblages indicative of ice free conditions 1–2 months of the year, and dominated by Nitzschia species became prevalent some time around 2000–2700 yr B.P. The occurrence of Chaetoceros spp. diatom spore-dominated assemblages, and increased abundances of benthic and planktonic foraminifera, ostracods, and diatoms, coupled with carbon- and oxygen-isotope changes around 2700–3400 yr B.P. strongly suggests that this area of the shelf experienced conditions conducive to increased productivity during this time period. Based on diatom assemblage associations recognized in modern environments, the upper water column of Fram Bank shelf waters was probably stratified during that time due to the presence of low-salinity melt water and a very shallow mixed layer, protected from storms, with sea-ice cover for less than 10 months per year. The close correspondence of δ13C and δ18O values from N. pachyderma (r2 = 0.74) throughout one core suggests that whatever oceanographic conditions influenced δ18O also influenced δ13C. Changes in Prydz Bay microfossil abundances and isotopes may result from alterations in circulation patterns, upwelling conditions, or sea-ice patterns which significantly affected benthic and planktonic productivity in the area. The environmental conditions indicated by older sediments in the cores are less clear, but an ice tongue may have been in place 3200–3800 yr B.P., and minor fluctuations in productivity are indicated around 6000 and 7000–7500 yr B.P. The lower 100 cm of both cores may not represent in situ deposition, but if the corrected AMS dates reflect the actual age of the sediments analyzed, microfossil and isotope data indicate that productivity, and oceanographic conditions were very variable around 8500-8600 yr B.P. The chronology adopted herein must be regarded as tentative until further study of the area has been undèrtaken.</div></front></TEI><affiliations><list><country><li>Australie</li><li>France</li><li>États-Unis</li></country><region><li>Californie</li></region></list><tree><country name="Australie"><noRegion><name sortKey="Rathburn, A E" sort="Rathburn, A E" uniqKey="Rathburn A" first="A. E." last="Rathburn">A. E. Rathburn</name></noRegion><name sortKey="Ayress, M A" sort="Ayress, M A" uniqKey="Ayress M" first="M. A." last="Ayress">M. A. Ayress</name><name sortKey="De Deckker, P" sort="De Deckker, P" uniqKey="De Deckker P" first="P." last="De Deckker">P. De Deckker</name></country><country name="États-Unis"><region name="Californie"><name sortKey="Rathburn, A E" sort="Rathburn, A E" uniqKey="Rathburn A" first="A. E." last="Rathburn">A. E. Rathburn</name></region></country><country name="France"><noRegion><name sortKey="Pichon, J J" sort="Pichon, J J" uniqKey="Pichon J" first="J.-J." last="Pichon">J.-J. Pichon</name></noRegion></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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