Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum
Identifieur interne : 002798 ( Istex/Corpus ); précédent : 002797; suivant : 002799Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum
Auteurs : Ross Edwards ; Peter Sedwick ; Vin Morgan ; Claude BoutronSource :
- Geochemistry, Geophysics, Geosystems [ 1525-2027 ] ; 2006-12.
English descriptors
- KwdEn :
- Accumulation rate, Accumulation rates, Aeolian dust, Aerosol iron, Algal production, Annual layers, Annual rates, Antarctic, Antarctic coast, Antarctic plateau, Antarctic plateau sites, Antarctic region, Antarctic snow, Antarctic snowmelt waters, Antarctic waters, Antarctica, Atmospheric, Atmospheric deposition, Atmospheric dust, Atmospheric iron deposition, Atmospheric iron flux, Atmospheric iron fluxes, Atmospheric iron supply, Atmospheric transport, Australian continent, Australian droughts, Australian dust, Available iron, Average tdfe concentration, Bhc1, Bhc1 core, Biogeochem, Biological availability, Boutron, Calendar year, Calendar years, Cape folger, Climatic implications, Coastal sites, Core chronology, Core data data, Core records, Core samples, Core section, Core sections, Decadal timescales, Delmonte, Deo8, Deposition, Deposition estimates, Deposition flux, Dome, Dome figure, Dome region, Dome summit, Drought conditions, Dust concentrations, Dust deposition, Dust particles, Early holocene, Early holocene mmol, Earth planet, East antarctic, East antarctica, Edwards, Eolian, Eolian dust, Eolian iron, Eolian iron deposition, Eolian iron flux, Eolian iron fluxes, Eolian iron supply, Epica, Epica dome, Flow injection analysis, Flux estimates, Fractional solubility, Gaspari, Geochemistry, Geochemistry geophysics geosystems, Geophys, Geophysics, Geosystems, Glacial, Glacial cycles, Glacial iron hypothesis, Glacial periods, Glacial times, Glaciol, Global, Global biogeochem, Good agreement, High rates, Highest tdfe concentrations, Holocene, Hydrochloric acid, Iron availability, Iron concentrations, Iron deposition, Iron deposition estimates, Iron deposition fluxes, Iron flux, Iron fluxes, Iron hypothesis, Iron supply, Last deglaciation, Lett, Lorius, Mahowald, Marine sediments, Meltwater samples, Mineral dust, Mmol, Model simulations, Modeling, Modeling studies, Modern snow, Past deposition, Phytoplankton, Phytoplankton production, Possible explanation, Present results, Primary production, Relative timing, Ridgwell, Seasonal variations, Sedwick, Significant meridional, Southern ocean, Study edwards, Surface ocean, Tdfe, Tdfe concentration, Tdfe concentrations, Time variation, Total dissolvable iron, Total iron, Trace metals, Uptake ratio, Vostok, Vostok sites, Wilkes land, Zonal gradients.
- Teeft :
- Accumulation rate, Accumulation rates, Aeolian dust, Aerosol iron, Algal production, Annual layers, Annual rates, Antarctic, Antarctic coast, Antarctic plateau, Antarctic plateau sites, Antarctic region, Antarctic snow, Antarctic snowmelt waters, Antarctic waters, Antarctica, Atmospheric, Atmospheric deposition, Atmospheric dust, Atmospheric iron deposition, Atmospheric iron flux, Atmospheric iron fluxes, Atmospheric iron supply, Atmospheric transport, Australian continent, Australian droughts, Australian dust, Available iron, Average tdfe concentration, Bhc1, Bhc1 core, Biogeochem, Biological availability, Boutron, Calendar year, Calendar years, Cape folger, Climatic implications, Coastal sites, Core chronology, Core data data, Core records, Core samples, Core section, Core sections, Decadal timescales, Delmonte, Deo8, Deposition, Deposition estimates, Deposition flux, Dome, Dome figure, Dome region, Dome summit, Drought conditions, Dust concentrations, Dust deposition, Dust particles, Early holocene, Early holocene mmol, Earth planet, East antarctic, East antarctica, Edwards, Eolian, Eolian dust, Eolian iron, Eolian iron deposition, Eolian iron flux, Eolian iron fluxes, Eolian iron supply, Epica, Epica dome, Flow injection analysis, Flux estimates, Fractional solubility, Gaspari, Geochemistry, Geochemistry geophysics geosystems, Geophys, Geophysics, Geosystems, Glacial, Glacial cycles, Glacial iron hypothesis, Glacial periods, Glacial times, Glaciol, Global, Global biogeochem, Good agreement, High rates, Highest tdfe concentrations, Holocene, Hydrochloric acid, Iron availability, Iron concentrations, Iron deposition, Iron deposition estimates, Iron deposition fluxes, Iron flux, Iron fluxes, Iron hypothesis, Iron supply, Last deglaciation, Lett, Lorius, Mahowald, Marine sediments, Meltwater samples, Mineral dust, Mmol, Model simulations, Modeling, Modeling studies, Modern snow, Past deposition, Phytoplankton, Phytoplankton production, Possible explanation, Present results, Primary production, Relative timing, Ridgwell, Seasonal variations, Sedwick, Significant meridional, Southern ocean, Study edwards, Surface ocean, Tdfe, Tdfe concentration, Tdfe concentrations, Time variation, Total dissolvable iron, Total iron, Trace metals, Uptake ratio, Vostok, Vostok sites, Wilkes land, Zonal gradients.
Abstract
Total dissolvable iron (TDFe) was measured in sections of ice cores recovered from Law Dome on the coast of Wilkes Land, East Antarctica. These samples include ice dating from the Last Glacial Maximum (LGM), the Last Deglaciation, and the early and mid Holocene as well as samples from the Anthropocene that have been dated with seasonal to annual resolution. Combining our TDFe concentration data with estimates of the ice accumulation rate, we estimate the atmospheric iron deposition for Law Dome and the adjacent Southern Ocean during these periods. Our results indicate that the atmospheric iron deposition flux to this region during the LGM (∼8 μmol Fe m−2 yr−1) was an order of magnitude higher than the average Holocene deposition flux (∼0.8 μmol Fe m−2 yr−1). This Holocene flux estimate is significantly higher than recent estimates of atmospheric iron deposition based on the analysis of iron in samples of the Dome C EPICA ice core, implying that there are significant meridional gradients in eolian iron flux to the Antarctic region. Our data also suggest that there have been significant variations in atmospheric iron deposition to Law Dome and adjacent ocean waters over seasonal to decadal timescales during the past century. Analysis of ice samples dating from calendar years 1927 to 1928 indicates an anomalously high flux of TDFe to the Law Dome region, amounting to around half the maximum LGM flux, possibly as a result of severe drought conditions on the Australian continent. Given that chronic iron deficiency is thought to limit phytoplankton production in much of the ocean around Antarctica, such large secular variations in atmospheric iron supply are likely to have had profound impacts on year‐to‐year primary production and ecosystem structure in Antarctic waters.
Url:
DOI: 10.1029/2006GC001307
Links to Exploration step
ISTEX:D6304D96D44B1221212AA332B801A6A83DFF5188Le document en format XML
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Bermuda</mods:affiliation></affiliation><affiliation><mods:affiliation>Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Hobart, Tasmania, Australia</mods:affiliation></affiliation></author><author><name sortKey="Morgan, Vin" sort="Morgan, Vin" uniqKey="Morgan V" first="Vin" last="Morgan">Vin Morgan</name><affiliation><mods:affiliation>Antarctic Climate and Ecosystems Cooperative Research Center, 7001, Hobart, Tasmania, Australia</mods:affiliation></affiliation><affiliation><mods:affiliation>Australian Antarctic Division, Kingston, Tasmania, Australia</mods:affiliation></affiliation></author><author><name sortKey="Boutron, Claude" sort="Boutron, Claude" uniqKey="Boutron C" first="Claude" last="Boutron">Claude Boutron</name><affiliation><mods:affiliation>Laboratoire de Glaciologie et Géophysique de l'Environnement du CNRS, 54 Rue Molière,, F‐38402, St. Martin d'Hères Cedex, France</mods:affiliation></affiliation></author></titleStmt><publicationStmt><idno type="wicri:source">ISTEX</idno><idno type="RBID">ISTEX:D6304D96D44B1221212AA332B801A6A83DFF5188</idno><date when="2006" year="2006">2006</date><idno type="doi">10.1029/2006GC001307</idno><idno type="url">https://api.istex.fr/document/D6304D96D44B1221212AA332B801A6A83DFF5188/fulltext/pdf</idno><idno type="wicri:Area/Istex/Corpus">002798</idno><idno type="wicri:explorRef" wicri:stream="Istex" wicri:step="Corpus" wicri:corpus="ISTEX">002798</idno></publicationStmt><sourceDesc><biblStruct><analytic><title level="a" type="main">Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum</title><author><name sortKey="Edwards, Ross" sort="Edwards, Ross" uniqKey="Edwards R" first="Ross" last="Edwards">Ross Edwards</name><affiliation><mods:affiliation>E-mail: redwards@dri.edu</mods:affiliation></affiliation><affiliation><mods:affiliation>Desert Research Institute, 2215 Raggio Parkway,, Nevada, 89512, Reno, USA</mods:affiliation></affiliation><affiliation><mods:affiliation>E-mail: redwards@dri.edu</mods:affiliation></affiliation></author><author><name sortKey="Sedwick, Peter" sort="Sedwick, Peter" uniqKey="Sedwick P" first="Peter" last="Sedwick">Peter Sedwick</name><affiliation><mods:affiliation>Bermuda Biological Station for Research, GE01, Ferry Reach, St. George's, Bermuda</mods:affiliation></affiliation><affiliation><mods:affiliation>Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Hobart, Tasmania, Australia</mods:affiliation></affiliation></author><author><name sortKey="Morgan, Vin" sort="Morgan, Vin" uniqKey="Morgan V" first="Vin" last="Morgan">Vin Morgan</name><affiliation><mods:affiliation>Antarctic Climate and Ecosystems Cooperative Research Center, 7001, Hobart, Tasmania, Australia</mods:affiliation></affiliation><affiliation><mods:affiliation>Australian Antarctic Division, Kingston, Tasmania, Australia</mods:affiliation></affiliation></author><author><name sortKey="Boutron, Claude" sort="Boutron, Claude" uniqKey="Boutron C" first="Claude" last="Boutron">Claude Boutron</name><affiliation><mods:affiliation>Laboratoire de Glaciologie et Géophysique de l'Environnement du CNRS, 54 Rue Molière,, F‐38402, St. Martin d'Hères Cedex, France</mods:affiliation></affiliation></author></analytic><monogr></monogr><series><title level="j" type="main">Geochemistry, Geophysics, Geosystems</title><title level="j" type="alt">GEOCHEMISTRY, GEOPHYSICS, GEOSYSTEMS</title><idno type="ISSN">1525-2027</idno><idno type="eISSN">1525-2027</idno><imprint><biblScope unit="vol">7</biblScope><biblScope unit="issue">12</biblScope><biblScope unit="page-count">15</biblScope><date type="published" when="2006-12">2006-12</date></imprint><idno type="ISSN">1525-2027</idno></series></biblStruct></sourceDesc><seriesStmt><idno type="ISSN">1525-2027</idno></seriesStmt></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Accumulation rate</term><term>Accumulation rates</term><term>Aeolian dust</term><term>Aerosol iron</term><term>Algal production</term><term>Annual layers</term><term>Annual rates</term><term>Antarctic</term><term>Antarctic coast</term><term>Antarctic plateau</term><term>Antarctic plateau sites</term><term>Antarctic region</term><term>Antarctic snow</term><term>Antarctic snowmelt waters</term><term>Antarctic waters</term><term>Antarctica</term><term>Atmospheric</term><term>Atmospheric deposition</term><term>Atmospheric dust</term><term>Atmospheric iron deposition</term><term>Atmospheric iron flux</term><term>Atmospheric iron fluxes</term><term>Atmospheric iron supply</term><term>Atmospheric transport</term><term>Australian continent</term><term>Australian droughts</term><term>Australian dust</term><term>Available iron</term><term>Average tdfe concentration</term><term>Bhc1</term><term>Bhc1 core</term><term>Biogeochem</term><term>Biological availability</term><term>Boutron</term><term>Calendar year</term><term>Calendar years</term><term>Cape folger</term><term>Climatic implications</term><term>Coastal sites</term><term>Core chronology</term><term>Core data data</term><term>Core records</term><term>Core samples</term><term>Core section</term><term>Core sections</term><term>Decadal timescales</term><term>Delmonte</term><term>Deo8</term><term>Deposition</term><term>Deposition estimates</term><term>Deposition flux</term><term>Dome</term><term>Dome figure</term><term>Dome region</term><term>Dome summit</term><term>Drought conditions</term><term>Dust concentrations</term><term>Dust deposition</term><term>Dust particles</term><term>Early holocene</term><term>Early holocene mmol</term><term>Earth planet</term><term>East antarctic</term><term>East antarctica</term><term>Edwards</term><term>Eolian</term><term>Eolian dust</term><term>Eolian iron</term><term>Eolian iron deposition</term><term>Eolian iron flux</term><term>Eolian iron fluxes</term><term>Eolian iron supply</term><term>Epica</term><term>Epica dome</term><term>Flow injection analysis</term><term>Flux estimates</term><term>Fractional solubility</term><term>Gaspari</term><term>Geochemistry</term><term>Geochemistry geophysics geosystems</term><term>Geophys</term><term>Geophysics</term><term>Geosystems</term><term>Glacial</term><term>Glacial cycles</term><term>Glacial iron hypothesis</term><term>Glacial periods</term><term>Glacial times</term><term>Glaciol</term><term>Global</term><term>Global biogeochem</term><term>Good agreement</term><term>High rates</term><term>Highest tdfe concentrations</term><term>Holocene</term><term>Hydrochloric acid</term><term>Iron availability</term><term>Iron concentrations</term><term>Iron deposition</term><term>Iron deposition estimates</term><term>Iron deposition fluxes</term><term>Iron flux</term><term>Iron fluxes</term><term>Iron hypothesis</term><term>Iron supply</term><term>Last deglaciation</term><term>Lett</term><term>Lorius</term><term>Mahowald</term><term>Marine sediments</term><term>Meltwater samples</term><term>Mineral dust</term><term>Mmol</term><term>Model simulations</term><term>Modeling</term><term>Modeling studies</term><term>Modern snow</term><term>Past deposition</term><term>Phytoplankton</term><term>Phytoplankton production</term><term>Possible explanation</term><term>Present results</term><term>Primary production</term><term>Relative timing</term><term>Ridgwell</term><term>Seasonal variations</term><term>Sedwick</term><term>Significant meridional</term><term>Southern ocean</term><term>Study edwards</term><term>Surface ocean</term><term>Tdfe</term><term>Tdfe concentration</term><term>Tdfe concentrations</term><term>Time variation</term><term>Total dissolvable iron</term><term>Total iron</term><term>Trace metals</term><term>Uptake ratio</term><term>Vostok</term><term>Vostok sites</term><term>Wilkes land</term><term>Zonal gradients</term></keywords><keywords scheme="Teeft" xml:lang="en"><term>Accumulation rate</term><term>Accumulation rates</term><term>Aeolian dust</term><term>Aerosol iron</term><term>Algal production</term><term>Annual layers</term><term>Annual rates</term><term>Antarctic</term><term>Antarctic coast</term><term>Antarctic plateau</term><term>Antarctic plateau sites</term><term>Antarctic region</term><term>Antarctic snow</term><term>Antarctic snowmelt waters</term><term>Antarctic waters</term><term>Antarctica</term><term>Atmospheric</term><term>Atmospheric deposition</term><term>Atmospheric dust</term><term>Atmospheric iron deposition</term><term>Atmospheric iron flux</term><term>Atmospheric iron fluxes</term><term>Atmospheric iron supply</term><term>Atmospheric transport</term><term>Australian continent</term><term>Australian droughts</term><term>Australian dust</term><term>Available iron</term><term>Average tdfe concentration</term><term>Bhc1</term><term>Bhc1 core</term><term>Biogeochem</term><term>Biological availability</term><term>Boutron</term><term>Calendar year</term><term>Calendar years</term><term>Cape folger</term><term>Climatic implications</term><term>Coastal sites</term><term>Core chronology</term><term>Core data data</term><term>Core records</term><term>Core samples</term><term>Core section</term><term>Core sections</term><term>Decadal timescales</term><term>Delmonte</term><term>Deo8</term><term>Deposition</term><term>Deposition estimates</term><term>Deposition flux</term><term>Dome</term><term>Dome figure</term><term>Dome region</term><term>Dome summit</term><term>Drought conditions</term><term>Dust concentrations</term><term>Dust deposition</term><term>Dust particles</term><term>Early holocene</term><term>Early holocene mmol</term><term>Earth planet</term><term>East antarctic</term><term>East antarctica</term><term>Edwards</term><term>Eolian</term><term>Eolian dust</term><term>Eolian iron</term><term>Eolian iron deposition</term><term>Eolian iron flux</term><term>Eolian iron fluxes</term><term>Eolian iron supply</term><term>Epica</term><term>Epica dome</term><term>Flow injection analysis</term><term>Flux estimates</term><term>Fractional solubility</term><term>Gaspari</term><term>Geochemistry</term><term>Geochemistry geophysics geosystems</term><term>Geophys</term><term>Geophysics</term><term>Geosystems</term><term>Glacial</term><term>Glacial cycles</term><term>Glacial iron hypothesis</term><term>Glacial periods</term><term>Glacial times</term><term>Glaciol</term><term>Global</term><term>Global biogeochem</term><term>Good agreement</term><term>High rates</term><term>Highest tdfe concentrations</term><term>Holocene</term><term>Hydrochloric acid</term><term>Iron availability</term><term>Iron concentrations</term><term>Iron deposition</term><term>Iron deposition estimates</term><term>Iron deposition fluxes</term><term>Iron flux</term><term>Iron fluxes</term><term>Iron hypothesis</term><term>Iron supply</term><term>Last deglaciation</term><term>Lett</term><term>Lorius</term><term>Mahowald</term><term>Marine sediments</term><term>Meltwater samples</term><term>Mineral dust</term><term>Mmol</term><term>Model simulations</term><term>Modeling</term><term>Modeling studies</term><term>Modern snow</term><term>Past deposition</term><term>Phytoplankton</term><term>Phytoplankton production</term><term>Possible explanation</term><term>Present results</term><term>Primary production</term><term>Relative timing</term><term>Ridgwell</term><term>Seasonal variations</term><term>Sedwick</term><term>Significant meridional</term><term>Southern ocean</term><term>Study edwards</term><term>Surface ocean</term><term>Tdfe</term><term>Tdfe concentration</term><term>Tdfe concentrations</term><term>Time variation</term><term>Total dissolvable iron</term><term>Total iron</term><term>Trace metals</term><term>Uptake ratio</term><term>Vostok</term><term>Vostok sites</term><term>Wilkes land</term><term>Zonal gradients</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract">Total dissolvable iron (TDFe) was measured in sections of ice cores recovered from Law Dome on the coast of Wilkes Land, East Antarctica. These samples include ice dating from the Last Glacial Maximum (LGM), the Last Deglaciation, and the early and mid Holocene as well as samples from the Anthropocene that have been dated with seasonal to annual resolution. Combining our TDFe concentration data with estimates of the ice accumulation rate, we estimate the atmospheric iron deposition for Law Dome and the adjacent Southern Ocean during these periods. Our results indicate that the atmospheric iron deposition flux to this region during the LGM (∼8 μmol Fe m−2 yr−1) was an order of magnitude higher than the average Holocene deposition flux (∼0.8 μmol Fe m−2 yr−1). This Holocene flux estimate is significantly higher than recent estimates of atmospheric iron deposition based on the analysis of iron in samples of the Dome C EPICA ice core, implying that there are significant meridional gradients in eolian iron flux to the Antarctic region. Our data also suggest that there have been significant variations in atmospheric iron deposition to Law Dome and adjacent ocean waters over seasonal to decadal timescales during the past century. Analysis of ice samples dating from calendar years 1927 to 1928 indicates an anomalously high flux of TDFe to the Law Dome region, amounting to around half the maximum LGM flux, possibly as a result of severe drought conditions on the Australian continent. Given that chronic iron deficiency is thought to limit phytoplankton production in much of the ocean around Antarctica, such large secular variations in atmospheric iron supply are likely to have had profound impacts on year‐to‐year primary production and ecosystem structure in Antarctic waters.</div></front></TEI><istex><corpusName>wiley</corpusName><keywords><teeft><json:string>holocene</json:string><json:string>antarctic</json:string><json:string>tdfe</json:string><json:string>southern ocean</json:string><json:string>bhc1</json:string><json:string>eolian</json:string><json:string>glacial</json:string><json:string>antarctica</json:string><json:string>atmospheric iron deposition</json:string><json:string>mmol</json:string><json:string>gaspari</json:string><json:string>sedwick</json:string><json:string>vostok</json:string><json:string>geophys</json:string><json:string>geosystems</json:string><json:string>geochemistry geophysics geosystems</json:string><json:string>geophysics</json:string><json:string>deposition</json:string><json:string>delmonte</json:string><json:string>phytoplankton</json:string><json:string>mahowald</json:string><json:string>aerosol iron</json:string><json:string>biogeochem</json:string><json:string>glaciol</json:string><json:string>global biogeochem</json:string><json:string>east antarctica</json:string><json:string>lett</json:string><json:string>ridgwell</json:string><json:string>core sections</json:string><json:string>deo8</json:string><json:string>dome summit</json:string><json:string>boutron</json:string><json:string>epica</json:string><json:string>lorius</json:string><json:string>accumulation rate</json:string><json:string>edwards</json:string><json:string>tdfe concentrations</json:string><json:string>core samples</json:string><json:string>total iron</json:string><json:string>deposition flux</json:string><json:string>dust deposition</json:string><json:string>core records</json:string><json:string>dome figure</json:string><json:string>modeling</json:string><json:string>earth planet</json:string><json:string>glacial periods</json:string><json:string>antarctic snow</json:string><json:string>eolian iron flux</json:string><json:string>early holocene</json:string><json:string>iron concentrations</json:string><json:string>atmospheric deposition</json:string><json:string>tdfe concentration</json:string><json:string>iron deposition</json:string><json:string>mineral dust</json:string><json:string>accumulation rates</json:string><json:string>dome region</json:string><json:string>surface ocean</json:string><json:string>calendar years</json:string><json:string>model simulations</json:string><json:string>atmospheric</json:string><json:string>geochemistry</json:string><json:string>dome</json:string><json:string>antarctic plateau</json:string><json:string>wilkes land</json:string><json:string>dust particles</json:string><json:string>eolian iron</json:string><json:string>last deglaciation</json:string><json:string>good agreement</json:string><json:string>modeling studies</json:string><json:string>antarctic waters</json:string><json:string>atmospheric iron flux</json:string><json:string>biological availability</json:string><json:string>seasonal variations</json:string><json:string>relative timing</json:string><json:string>glacial iron hypothesis</json:string><json:string>australian continent</json:string><json:string>primary production</json:string><json:string>global</json:string><json:string>total dissolvable iron</json:string><json:string>flux estimates</json:string><json:string>east antarctic</json:string><json:string>atmospheric dust</json:string><json:string>deposition estimates</json:string><json:string>bhc1 core</json:string><json:string>cape folger</json:string><json:string>core chronology</json:string><json:string>annual layers</json:string><json:string>aeolian dust</json:string><json:string>available iron</json:string><json:string>hydrochloric acid</json:string><json:string>meltwater samples</json:string><json:string>coastal sites</json:string><json:string>antarctic snowmelt waters</json:string><json:string>antarctic region</json:string><json:string>flow injection analysis</json:string><json:string>glacial times</json:string><json:string>high rates</json:string><json:string>highest tdfe concentrations</json:string><json:string>average tdfe concentration</json:string><json:string>drought conditions</json:string><json:string>australian dust</json:string><json:string>calendar year</json:string><json:string>core section</json:string><json:string>eolian iron deposition</json:string><json:string>antarctic plateau sites</json:string><json:string>iron hypothesis</json:string><json:string>dust concentrations</json:string><json:string>marine sediments</json:string><json:string>eolian iron fluxes</json:string><json:string>glacial cycles</json:string><json:string>annual rates</json:string><json:string>vostok sites</json:string><json:string>modern snow</json:string><json:string>iron deposition estimates</json:string><json:string>early holocene mmol</json:string><json:string>possible explanation</json:string><json:string>decadal timescales</json:string><json:string>atmospheric iron supply</json:string><json:string>iron flux</json:string><json:string>core data data</json:string><json:string>study edwards</json:string><json:string>antarctic coast</json:string><json:string>iron deposition fluxes</json:string><json:string>atmospheric transport</json:string><json:string>epica dome</json:string><json:string>phytoplankton production</json:string><json:string>fractional solubility</json:string><json:string>eolian dust</json:string><json:string>iron fluxes</json:string><json:string>atmospheric iron fluxes</json:string><json:string>eolian iron supply</json:string><json:string>australian droughts</json:string><json:string>significant meridional</json:string><json:string>past deposition</json:string><json:string>zonal gradients</json:string><json:string>uptake ratio</json:string><json:string>trace metals</json:string><json:string>climatic implications</json:string><json:string>present results</json:string><json:string>iron supply</json:string><json:string>iron availability</json:string><json:string>time variation</json:string><json:string>algal production</json:string></teeft></keywords><author><json:item><name>Ross Edwards</name><affiliations><json:string>E-mail: redwards@dri.edu</json:string><json:string>Desert Research Institute, 2215 Raggio Parkway,, Nevada, 89512, Reno, USA</json:string><json:string>E-mail: redwards@dri.edu</json:string></affiliations></json:item><json:item><name>Peter Sedwick</name><affiliations><json:string>Bermuda Biological Station for Research, GE01, Ferry Reach, St. George's, Bermuda</json:string><json:string>Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Hobart, Tasmania, Australia</json:string></affiliations></json:item><json:item><name>Vin Morgan</name><affiliations><json:string>Antarctic Climate and Ecosystems Cooperative Research Center, 7001, Hobart, Tasmania, Australia</json:string><json:string>Australian Antarctic Division, Kingston, Tasmania, Australia</json:string></affiliations></json:item><json:item><name>Claude Boutron</name><affiliations><json:string>Laboratoire de Glaciologie et Géophysique de l'Environnement du CNRS, 54 Rue Molière,, F‐38402, St. Martin d'Hères Cedex, France</json:string></affiliations></json:item></author><subject><json:item><lang><json:string>eng</json:string></lang><value>atmospheric iron deposition</value></json:item><json:item><lang><json:string>eng</json:string></lang><value>Antarctica</value></json:item><json:item><lang><json:string>eng</json:string></lang><value>Southern Ocean</value></json:item><json:item><lang><json:string>eng</json:string></lang><value>Last Glacial Maximum</value></json:item></subject><articleId><json:string>2006GC001307</json:string></articleId><arkIstex>ark:/67375/WNG-WW80586L-2</arkIstex><language><json:string>eng</json:string></language><originalGenre><json:string>letter</json:string></originalGenre><abstract>Total dissolvable iron (TDFe) was measured in sections of ice cores recovered from Law Dome on the coast of Wilkes Land, East Antarctica. These samples include ice dating from the Last Glacial Maximum (LGM), the Last Deglaciation, and the early and mid Holocene as well as samples from the Anthropocene that have been dated with seasonal to annual resolution. Combining our TDFe concentration data with estimates of the ice accumulation rate, we estimate the atmospheric iron deposition for Law Dome and the adjacent Southern Ocean during these periods. Our results indicate that the atmospheric iron deposition flux to this region during the LGM (∼8 μmol Fe m−2 yr−1) was an order of magnitude higher than the average Holocene deposition flux (∼0.8 μmol Fe m−2 yr−1). This Holocene flux estimate is significantly higher than recent estimates of atmospheric iron deposition based on the analysis of iron in samples of the Dome C EPICA ice core, implying that there are significant meridional gradients in eolian iron flux to the Antarctic region. Our data also suggest that there have been significant variations in atmospheric iron deposition to Law Dome and adjacent ocean waters over seasonal to decadal timescales during the past century. Analysis of ice samples dating from calendar years 1927 to 1928 indicates an anomalously high flux of TDFe to the Law Dome region, amounting to around half the maximum LGM flux, possibly as a result of severe drought conditions on the Australian continent. Given that chronic iron deficiency is thought to limit phytoplankton production in much of the ocean around Antarctica, such large secular variations in atmospheric iron supply are likely to have had profound impacts on year‐to‐year primary production and ecosystem structure in Antarctic waters.</abstract><qualityIndicators><score>10</score><pdfWordCount>7955</pdfWordCount><pdfCharCount>48414</pdfCharCount><pdfVersion>1.4</pdfVersion><pdfPageCount>15</pdfPageCount><pdfPageSize>612 x 792 pts (letter)</pdfPageSize><refBibsNative>true</refBibsNative><abstractWordCount>285</abstractWordCount><abstractCharCount>1796</abstractCharCount><keywordCount>4</keywordCount></qualityIndicators><title>Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum</title><genre><json:string>review-article</json:string></genre><host><title>Geochemistry, Geophysics, Geosystems</title><language><json:string>unknown</json:string></language><doi><json:string>10.1002/(ISSN)1525-2027</json:string></doi><issn><json:string>1525-2027</json:string></issn><eissn><json:string>1525-2027</json:string></eissn><publisherId><json:string>GGGE</json:string></publisherId><volume>7</volume><issue>12</issue><pages><first>n/a</first><last>n/a</last><total>15</total></pages><genre><json:string>journal</json:string></genre><subject><json:item><value>Eolian Dust as a Player and Recorder of Environmental Change</value></json:item><json:item><value>ATMOSPHERIC COMPOSITION AND STRUCTURE</value></json:item><json:item><value>Biosphere/atmosphere interactions</value></json:item><json:item><value>BIOGEOSCIENCES</value></json:item><json:item><value>Biogeochemical cycles, processes, and modeling</value></json:item><json:item><value>Biogeochemical kinetics and reaction modeling</value></json:item><json:item><value>Biosphere/atmosphere interactions</value></json:item><json:item><value>CRYOSPHERE</value></json:item><json:item><value>Clathrate</value></json:item><json:item><value>Biogeochemistry</value></json:item><json:item><value>GLOBAL CHANGE</value></json:item><json:item><value>Biogeochemical cycles, processes, and modeling</value></json:item><json:item><value>Atmosphere</value></json:item><json:item><value>OCEANOGRAPHY: BIOLOGICAL AND CHEMICAL</value></json:item><json:item><value>Biogeochemical cycles, processes, and modeling</value></json:item><json:item><value>PALEOCEANOGRAPHY</value></json:item><json:item><value>Biogeochemical cycles, processes, and modeling</value></json:item></subject></host><namedEntities><unitex><date><json:string>1927 to 1928</json:string><json:string>1928</json:string><json:string>1997</json:string><json:string>1920s</json:string><json:string>2006</json:string><json:string>1930s</json:string></date><geogName><json:string>Tasman Sea</json:string></geogName><orgName><json:string>Australia Vin Morgan Antarctic Climate and Ecosystems</json:string><json:string>Cooperative Research Center</json:string><json:string>Australia Australian Antarctic Division, Kingston, Tasmania, Australia Claude Boutron Laboratoire</json:string><json:string>Geochem</json:string><json:string>Environmental Change Guest Editors</json:string><json:string>Bermuda Institute of Antarctic and Southern Ocean</json:string><json:string>Australia and South America</json:string><json:string>Cooperative Research Center for Antarctica</json:string><json:string>American Geophysical Union</json:string><json:string>Research, Ferry Reach, St</json:string><json:string>University of Tasmania</json:string></orgName><orgName_funder></orgName_funder><orgName_provider></orgName_provider><persName><json:string>Ian Allison</json:string><json:string>Vostok</json:string><json:string>Sedwick</json:string><json:string>Time Span</json:string><json:string>Recorder</json:string><json:string>Maarten Prins</json:string><json:string>E. 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McConnell</json:string></persName><placeName><json:string>Australia</json:string><json:string>Victoria</json:string><json:string>America</json:string><json:string>New Zealand</json:string><json:string>France</json:string><json:string>Hobart</json:string></placeName><ref_url></ref_url><ref_bibl><json:string>Last Glacial Maximum Ross Edwards Desert Research Institute, 2215</json:string><json:string>Grousset et al., 1992</json:string><json:string>Zoller et al., 1974</json:string><json:string>Blunier and Brook, 2001</json:string><json:string>Fung et al., 2000</json:string><json:string>Jickells and Spokes, 2001</json:string><json:string>Tegen and Fung, 1994</json:string><json:string>Brzezinski et al., 2002</json:string><json:string>Morgan and McCray, 1985</json:string><json:string>[12]</json:string><json:string>0426, 1610</json:string><json:string>Hinkley and Matsumoto, 2001</json:string><json:string>BP, 1997</json:string><json:string>Gaspari et al., 2006</json:string><json:string>Lunt and Valdes, 2002</json:string><json:string>Etheridge et al. 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[1999]</json:string><json:string>Vallelonga et al., 2002</json:string><json:string>Delmonte et al., 2004a, 2004b</json:string><json:string>Popova et al., 2000</json:string><json:string>Ridgwell et al., 2002</json:string><json:string>Dai et al., 1998, 2004</json:string><json:string>[9]</json:string><json:string>Morgan et al., 2002</json:string><json:string>de Baar et al., 2005</json:string><json:string>[2000]</json:string><json:string>Measures et al. [1995]</json:string><json:string>Crutzen and Stoermer, 2000</json:string><json:string>[1998]</json:string><json:string>Maggi and Petit, 1998</json:string><json:string>De Angelis et al., 1987</json:string><json:string>[2]</json:string><json:string>[24]</json:string><json:string>Etheridge et al., 1988</json:string><json:string>Kumar et al., 1995</json:string><json:string>Broecker and Henderson, 1998</json:string><json:string>Basile et al., 1997</json:string><json:string>Delmonte et al., 2004b, 2004c</json:string><json:string>Boutron and Lorius, 1979</json:string><json:string>Lefevre and Watson, 1999</json:string><json:string>Moore et al., 2000</json:string></ref_bibl><bibl></bibl></unitex></namedEntities><ark><json:string>ark:/67375/WNG-WW80586L-2</json:string></ark><categories><wos><json:string>1 - science</json:string><json:string>2 - geochemistry & geophysics</json:string></wos><scienceMetrix></scienceMetrix><scopus><json:string>1 - Physical Sciences</json:string><json:string>2 - Earth and Planetary Sciences</json:string><json:string>3 - Geochemistry and Petrology</json:string><json:string>1 - Physical Sciences</json:string><json:string>2 - Earth and Planetary Sciences</json:string><json:string>3 - Geophysics</json:string></scopus></categories><publicationDate>2006</publicationDate><copyrightDate>2006</copyrightDate><doi><json:string>10.1029/2006GC001307</json:string></doi><id>D6304D96D44B1221212AA332B801A6A83DFF5188</id><score>1</score><fulltext><json:item><extension>pdf</extension><original>true</original><mimetype>application/pdf</mimetype><uri>https://api.istex.fr/document/D6304D96D44B1221212AA332B801A6A83DFF5188/fulltext/pdf</uri></json:item><json:item><extension>zip</extension><original>false</original><mimetype>application/zip</mimetype><uri>https://api.istex.fr/document/D6304D96D44B1221212AA332B801A6A83DFF5188/fulltext/zip</uri></json:item><istex:fulltextTEI 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A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum</title><title level="a" type="short">IRON IN ICE CORES FROM LAW DOME</title><author xml:id="author-0000"><persName><forename type="first">Ross</forename><surname>Edwards</surname></persName><email>redwards@dri.edu</email><affiliation><orgName>Desert Research Institute</orgName><address><street>2215 Raggio Parkway,</street><settlement type="city">Reno</settlement><postCode>89512</postCode><region>Nevada</region><country key="US">USA</country></address></affiliation></author><author xml:id="author-0001"><persName><forename type="first">Peter</forename><surname>Sedwick</surname></persName><affiliation><orgName>Bermuda Biological Station for Research</orgName><address><settlement type="city">Ferry Reach, St. George's</settlement><postCode>GE01</postCode><country key="BM">Bermuda</country></address></affiliation><affiliation><orgName>Institute of Antarctic and Southern Ocean Studies</orgName><orgName>University of Tasmania</orgName><address><settlement type="city">Hobart, Tasmania</settlement><country key="AU">Australia</country></address></affiliation></author><author xml:id="author-0002"><persName><forename type="first">Vin</forename><surname>Morgan</surname></persName><affiliation><orgName>Antarctic Climate and Ecosystems Cooperative Research Center</orgName><address><settlement type="city">Hobart, Tasmania</settlement><postCode>7001</postCode><country key="AU">Australia</country></address></affiliation><affiliation><orgName>Australian Antarctic Division</orgName><address><settlement type="city">Kingston, Tasmania</settlement><country key="AU">Australia</country></address></affiliation></author><author xml:id="author-0003"><persName><forename type="first">Claude</forename><surname>Boutron</surname></persName><affiliation><orgName>Laboratoire de Glaciologie et Géophysique de l'Environnement du CNRS</orgName><address><street>54 Rue Molière,</street><settlement type="city">St. Martin d'Hères Cedex</settlement><postCode>F‐38402</postCode><country key="FR">France</country></address></affiliation></author><idno type="istex">D6304D96D44B1221212AA332B801A6A83DFF5188</idno><idno type="ark">ark:/67375/WNG-WW80586L-2</idno><idno type="DOI">10.1029/2006GC001307</idno><idno type="editorialOffice">2006GC001307</idno><idno type="society">Q12Q01</idno><idno type="unit">GGGE919</idno><idno type="toTypesetVersion">file:GGGE.GGGE919.pdf</idno></analytic><monogr><title level="j" type="main">Geochemistry, Geophysics, Geosystems</title><title level="j" type="alt">GEOCHEMISTRY, GEOPHYSICS, GEOSYSTEMS</title><idno type="pISSN">1525-2027</idno><idno type="eISSN">1525-2027</idno><idno type="book-DOI">10.1002/(ISSN)1525-2027</idno><idno type="book-part-DOI">10.1002/ggge.v7.12</idno><idno type="product">GGGE</idno><idno type="coden">GGGGFR</idno><imprint><biblScope unit="vol">7</biblScope><biblScope unit="issue">12</biblScope><biblScope unit="page-count">15</biblScope><date type="published" when="2006-12"></date></imprint></monogr></biblStruct></sourceDesc></fileDesc><profileDesc><abstract style="main"><p xml:id="ggge919-para-0001">Total dissolvable iron (TDFe) was measured in sections of ice cores recovered from Law Dome on the coast of Wilkes Land, East Antarctica. These samples include ice dating from the Last Glacial Maximum (LGM), the Last Deglaciation, and the early and mid Holocene as well as samples from the Anthropocene that have been dated with seasonal to annual resolution. Combining our TDFe concentration data with estimates of the ice accumulation rate, we estimate the atmospheric iron deposition for Law Dome and the adjacent Southern Ocean during these periods. Our results indicate that the atmospheric iron deposition flux to this region during the LGM (∼8 <hi rend="italic">μ</hi>mol Fe m<hi rend="superscript">−2</hi> yr<hi rend="superscript">−1</hi>) was an order of magnitude higher than the average Holocene deposition flux (∼0.8 <hi rend="italic">μ</hi>mol Fe m<hi rend="superscript">−2</hi> yr<hi rend="superscript">−1</hi>). This Holocene flux estimate is significantly higher than recent estimates of atmospheric iron deposition based on the analysis of iron in samples of the Dome C EPICA ice core, implying that there are significant meridional gradients in eolian iron flux to the Antarctic region. Our data also suggest that there have been significant variations in atmospheric iron deposition to Law Dome and adjacent ocean waters over seasonal to decadal timescales during the past century. Analysis of ice samples dating from calendar years 1927 to 1928 indicates an anomalously high flux of TDFe to the Law Dome region, amounting to around half the maximum LGM flux, possibly as a result of severe drought conditions on the Australian continent. Given that chronic iron deficiency is thought to limit phytoplankton production in much of the ocean around Antarctica, such large secular variations in atmospheric iron supply are likely to have had profound impacts on year‐to‐year primary production and ecosystem structure in Antarctic waters.</p></abstract><textClass><keywords><term xml:id="ggge919-kwd-0001">atmospheric iron deposition</term><term xml:id="ggge919-kwd-0002">Antarctica</term><term xml:id="ggge919-kwd-0003">Southern Ocean</term><term xml:id="ggge919-kwd-0004">Last Glacial Maximum</term></keywords><classCode scheme="http://psi.agu.org/specialSection/EDUST1">Eolian Dust as a Player and Recorder of Environmental Change</classCode><classCode scheme="http://psi.agu.org/taxonomy5/0300">ATMOSPHERIC COMPOSITION AND STRUCTURE</classCode><classCode scheme="http://psi.agu.org/taxonomy5/0400">BIOGEOSCIENCES</classCode><classCode scheme="http://psi.agu.org/taxonomy5/0700">CRYOSPHERE</classCode><classCode scheme="http://psi.agu.org/taxonomy5/1600">GLOBAL CHANGE</classCode><classCode scheme="http://psi.agu.org/taxonomy5/4800">OCEANOGRAPHY: BIOLOGICAL AND CHEMICAL</classCode><classCode scheme="http://psi.agu.org/taxonomy5/4900">PALEOCEANOGRAPHY</classCode></textClass><langUsage><language ident="en"></language></langUsage></profileDesc></teiHeader></istex:fulltextTEI><json:item><extension>txt</extension><original>false</original><mimetype>text/plain</mimetype><uri>https://api.istex.fr/document/D6304D96D44B1221212AA332B801A6A83DFF5188/fulltext/txt</uri></json:item></fulltext><metadata><istex:metadataXml wicri:clean="Wiley, elements deleted: body"><istex:xmlDeclaration>version="1.0" encoding="UTF-8" standalone="yes"</istex:xmlDeclaration><istex:document><component type="serialArticle" version="2.0" xml:lang="en" xml:id="ggge919"><header><publicationMeta level="product"><doi>10.1002/(ISSN)1525-2027</doi><issn type="print">1525-2027</issn><issn type="electronic">1525-2027</issn><idGroup><id type="product" value="GGGE"></id><id type="coden" value="GGGGFR"></id></idGroup><titleGroup><title type="main" xml:lang="en" sort="GEOCHEMISTRY, GEOPHYSICS, GEOSYSTEMS">Geochemistry, Geophysics, Geosystems</title><title type="short">Geochem. Geophys. 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Geophys. Geosyst.</journalTitle>, <vol>7</vol>, Q12Q01, doi:<accessionId ref="info:doi/10.1029/2006GC001307">10.1029/2006GC001307</accessionId>.</citation></selfCitationGroup><linkGroup><link type="toTypesetVersion" href="file:GGGE.GGGE919.pdf"></link></linkGroup></publicationMeta><contentMeta><countGroup><count type="wordTotal" number="8777"></count><count type="figureTotal" number="7"></count><count type="tableTotal" number="4"></count></countGroup><titleGroup><title type="main">Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum</title><title type="short">IRON IN ICE CORES FROM LAW DOME</title><title type="shortAuthors">Edwards <i>et al</i>.</title></titleGroup><creators><creator creatorRole="author" xml:id="ggge919-cr-0001" affiliationRef="#ggge919-aff-0001"><personName><givenNames>Ross</givenNames> <familyName>Edwards</familyName></personName><contactDetails><email normalForm="redwards@dri.edu">redwards@dri.edu</email></contactDetails></creator><creator creatorRole="author" xml:id="ggge919-cr-0002" affiliationRef="#ggge919-aff-0002 #ggge919-aff-0003"><personName><givenNames>Peter</givenNames> <familyName>Sedwick</familyName></personName></creator><creator creatorRole="author" xml:id="ggge919-cr-0003" affiliationRef="#ggge919-aff-0004 #ggge919-aff-0005"><personName><givenNames>Vin</givenNames> <familyName>Morgan</familyName></personName></creator><creator creatorRole="author" xml:id="ggge919-cr-0004" affiliationRef="#ggge919-aff-0006"><personName><givenNames>Claude</givenNames> <familyName>Boutron</familyName></personName></creator></creators><affiliationGroup><affiliation countryCode="US" type="organization" xml:id="ggge919-aff-0001"><orgName>Desert Research Institute</orgName><address><street>2215 Raggio Parkway,</street><city>Reno</city><countryPart>Nevada</countryPart><postCode>89512</postCode><country>USA</country></address></affiliation><affiliation countryCode="BM" type="organization" xml:id="ggge919-aff-0002"><orgName>Bermuda Biological Station for Research</orgName><address><city>Ferry Reach, St. George's</city><postCode>GE01</postCode><country>Bermuda</country></address></affiliation><affiliation countryCode="AU" type="organization" xml:id="ggge919-aff-0003"><orgDiv>Institute of Antarctic and Southern Ocean Studies</orgDiv><orgName>University of Tasmania</orgName><address><city>Hobart, Tasmania</city><country>Australia</country></address></affiliation><affiliation countryCode="AU" type="organization" xml:id="ggge919-aff-0004"><orgName>Antarctic Climate and Ecosystems Cooperative Research Center</orgName><address><city>Hobart, Tasmania</city><postCode>7001</postCode><country>Australia</country></address></affiliation><affiliation countryCode="AU" type="organization" xml:id="ggge919-aff-0005"><orgName>Australian Antarctic Division</orgName><address><city>Kingston, Tasmania</city><country>Australia</country></address></affiliation><affiliation countryCode="FR" type="organization" xml:id="ggge919-aff-0006"><orgName>Laboratoire de Glaciologie et Géophysique de l'Environnement du CNRS</orgName><address><street>54 Rue Molière,</street><postCode>F‐38402</postCode><city>St. Martin d'Hères Cedex</city><country>France</country></address></affiliation></affiliationGroup><keywordGroup type="author"><keyword xml:id="ggge919-kwd-0001">atmospheric iron deposition</keyword><keyword xml:id="ggge919-kwd-0002">Antarctica</keyword><keyword xml:id="ggge919-kwd-0003">Southern Ocean</keyword><keyword xml:id="ggge919-kwd-0004">Last Glacial Maximum</keyword></keywordGroup><abstractGroup><abstract type="main"><p xml:id="ggge919-para-0001">Total dissolvable iron (TDFe) was measured in sections of ice cores recovered from Law Dome on the coast of Wilkes Land, East Antarctica. These samples include ice dating from the Last Glacial Maximum (LGM), the Last Deglaciation, and the early and mid Holocene as well as samples from the Anthropocene that have been dated with seasonal to annual resolution. Combining our TDFe concentration data with estimates of the ice accumulation rate, we estimate the atmospheric iron deposition for Law Dome and the adjacent Southern Ocean during these periods. Our results indicate that the atmospheric iron deposition flux to this region during the LGM (∼8 <i>μ</i>mol Fe m<sup>−2</sup> yr<sup>−1</sup>) was an order of magnitude higher than the average Holocene deposition flux (∼0.8 <i>μ</i>mol Fe m<sup>−2</sup> yr<sup>−1</sup>). This Holocene flux estimate is significantly higher than recent estimates of atmospheric iron deposition based on the analysis of iron in samples of the Dome C EPICA ice core, implying that there are significant meridional gradients in eolian iron flux to the Antarctic region. Our data also suggest that there have been significant variations in atmospheric iron deposition to Law Dome and adjacent ocean waters over seasonal to decadal timescales during the past century. Analysis of ice samples dating from calendar years 1927 to 1928 indicates an anomalously high flux of TDFe to the Law Dome region, amounting to around half the maximum LGM flux, possibly as a result of severe drought conditions on the Australian continent. Given that chronic iron deficiency is thought to limit phytoplankton production in much of the ocean around Antarctica, such large secular variations in atmospheric iron supply are likely to have had profound impacts on year‐to‐year primary production and ecosystem structure in Antarctic waters.</p></abstract></abstractGroup></contentMeta></header></component></istex:document></istex:metadataXml><mods version="3.6"><titleInfo lang="en"><title>Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum</title></titleInfo><titleInfo type="abbreviated" lang="en"><title>IRON IN ICE CORES FROM LAW DOME</title></titleInfo><titleInfo type="alternative" contentType="CDATA" lang="en"><title>Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum</title></titleInfo><name type="personal"><namePart type="given">Ross</namePart><namePart type="family">Edwards</namePart><affiliation>E-mail: redwards@dri.edu</affiliation><affiliation>Desert Research Institute, 2215 Raggio Parkway,, Nevada, 89512, Reno, USA</affiliation><affiliation>E-mail: redwards@dri.edu</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Peter</namePart><namePart type="family">Sedwick</namePart><affiliation>Bermuda Biological Station for Research, GE01, Ferry Reach, St. George's, Bermuda</affiliation><affiliation>Institute of Antarctic and Southern Ocean Studies, University of Tasmania, Hobart, Tasmania, Australia</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Vin</namePart><namePart type="family">Morgan</namePart><affiliation>Antarctic Climate and Ecosystems Cooperative Research Center, 7001, Hobart, Tasmania, Australia</affiliation><affiliation>Australian Antarctic Division, Kingston, Tasmania, Australia</affiliation><role><roleTerm type="text">author</roleTerm></role></name><name type="personal"><namePart type="given">Claude</namePart><namePart type="family">Boutron</namePart><affiliation>Laboratoire de Glaciologie et Géophysique de l'Environnement du CNRS, 54 Rue Molière,, F‐38402, St. Martin d'Hères Cedex, France</affiliation><role><roleTerm type="text">author</roleTerm></role></name><typeOfResource>text</typeOfResource><genre type="review-article" displayLabel="letter" authority="ISTEX" authorityURI="https://content-type.data.istex.fr" valueURI="https://content-type.data.istex.fr/ark:/67375/XTP-L5L7X3NF-P">review-article</genre><originInfo><publisher>Blackwell Publishing Ltd</publisher><dateIssued encoding="w3cdtf">2006-12</dateIssued><dateCaptured encoding="w3cdtf">2006-03-15</dateCaptured><dateValid encoding="w3cdtf">2006-09-11</dateValid><edition>Edwards, R., P. Sedwick, V. Morgan, and C. Boutron (2006), Iron in ice cores from Law Dome: A record of atmospheric iron deposition for maritime East Antarctica during the Holocene and Last Glacial Maximum, Geochem. Geophys. Geosyst., 7, Q12Q01, doi:10.1029/2006GC001307.</edition><copyrightDate encoding="w3cdtf">2006</copyrightDate></originInfo><language><languageTerm type="code" authority="rfc3066">en</languageTerm><languageTerm type="code" authority="iso639-2b">eng</languageTerm></language><physicalDescription><extent unit="figures">7</extent><extent unit="tables">4</extent><extent unit="words">8777</extent></physicalDescription><abstract>Total dissolvable iron (TDFe) was measured in sections of ice cores recovered from Law Dome on the coast of Wilkes Land, East Antarctica. These samples include ice dating from the Last Glacial Maximum (LGM), the Last Deglaciation, and the early and mid Holocene as well as samples from the Anthropocene that have been dated with seasonal to annual resolution. Combining our TDFe concentration data with estimates of the ice accumulation rate, we estimate the atmospheric iron deposition for Law Dome and the adjacent Southern Ocean during these periods. Our results indicate that the atmospheric iron deposition flux to this region during the LGM (∼8 μmol Fe m−2 yr−1) was an order of magnitude higher than the average Holocene deposition flux (∼0.8 μmol Fe m−2 yr−1). This Holocene flux estimate is significantly higher than recent estimates of atmospheric iron deposition based on the analysis of iron in samples of the Dome C EPICA ice core, implying that there are significant meridional gradients in eolian iron flux to the Antarctic region. Our data also suggest that there have been significant variations in atmospheric iron deposition to Law Dome and adjacent ocean waters over seasonal to decadal timescales during the past century. Analysis of ice samples dating from calendar years 1927 to 1928 indicates an anomalously high flux of TDFe to the Law Dome region, amounting to around half the maximum LGM flux, possibly as a result of severe drought conditions on the Australian continent. Given that chronic iron deficiency is thought to limit phytoplankton production in much of the ocean around Antarctica, such large secular variations in atmospheric iron supply are likely to have had profound impacts on year‐to‐year primary production and ecosystem structure in Antarctic waters.</abstract><subject><genre>keywords</genre><topic>atmospheric iron deposition</topic><topic>Antarctica</topic><topic>Southern Ocean</topic><topic>Last Glacial Maximum</topic></subject><relatedItem type="host"><titleInfo><title>Geochemistry, Geophysics, Geosystems</title></titleInfo><titleInfo type="abbreviated"><title>Geochem. Geophys. 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