Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica

Each summer the waters in McMurdo Sound (Lat. 77.5ºS; Long. 165ºE), south-western (SW) Ross Sea encounter vast phytoplankton blooms. This phenomenon is stimulated by the addition of bio-available iron (Fe) to an environment where phytoplankton growth is otherwise Fe-limited. One possible source of s...

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Bibliographic Details
Main Author: Winton, Victoria Holly Liberty (11686693)
Format: Thesis
Language:unknown
Published: 2012
Subjects:
Geophysics not elsewhere classified
Dust
Eolian iron
Antarctica
Ross Sea
McMurdo Sound
School: School of Geography
Environment and Earth Sciences
040499 Geophysics not elsewhere classified
Marsden: 260399 Geochemistry not Elsewhere Classified
Marsden: 260402 Chemical Oceanography
Marsden: 260602 Climatology (incl. Palaeoclimatology)
Marsden: 260104 Sedimentology
Degree Discipline: Geology
Degree Level: Masters
Degree Name: Master of Science
Southern Ocean
East Antarctica
McMurdo Ice Shelf
Marsden
Granite Harbour
Antarc*
Ice Shelf
Sea ice
Online Access:https://doi.org/10.26686/wgtn.16997761.v1
id ftsmithonian:oai:figshare.com:article/16997761
record_format openpolar
institution Open Polar
collection Unknown
op_collection_id ftsmithonian
language unknown
topic Geophysics not elsewhere classified
Dust
Eolian iron
Antarctica
Ross Sea
McMurdo Sound
School: School of Geography
Environment and Earth Sciences
040499 Geophysics not elsewhere classified
Marsden: 260399 Geochemistry not Elsewhere Classified
Marsden: 260402 Chemical Oceanography
Marsden: 260602 Climatology (incl. Palaeoclimatology)
Marsden: 260104 Sedimentology
Degree Discipline: Geology
Degree Level: Masters
Degree Name: Master of Science
spellingShingle Geophysics not elsewhere classified
Dust
Eolian iron
Antarctica
Ross Sea
McMurdo Sound
School: School of Geography
Environment and Earth Sciences
040499 Geophysics not elsewhere classified
Marsden: 260399 Geochemistry not Elsewhere Classified
Marsden: 260402 Chemical Oceanography
Marsden: 260602 Climatology (incl. Palaeoclimatology)
Marsden: 260104 Sedimentology
Degree Discipline: Geology
Degree Level: Masters
Degree Name: Master of Science
Winton, Victoria Holly Liberty (11686693)
Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica
topic_facet Geophysics not elsewhere classified
Dust
Eolian iron
Antarctica
Ross Sea
McMurdo Sound
School: School of Geography
Environment and Earth Sciences
040499 Geophysics not elsewhere classified
Marsden: 260399 Geochemistry not Elsewhere Classified
Marsden: 260402 Chemical Oceanography
Marsden: 260602 Climatology (incl. Palaeoclimatology)
Marsden: 260104 Sedimentology
Degree Discipline: Geology
Degree Level: Masters
Degree Name: Master of Science
description Each summer the waters in McMurdo Sound (Lat. 77.5ºS; Long. 165ºE), south-western (SW) Ross Sea encounter vast phytoplankton blooms. This phenomenon is stimulated by the addition of bio-available iron (Fe) to an environment where phytoplankton growth is otherwise Fe-limited. One possible source of such Fe is aeolian sand and dust (ASD) which accumulates on sea ice and is released into the ocean during the summer melt season. The amount of bio-available Fe (i.e. the amount of Fe immedately accessible to phytoplankton) potentially supplied to the ocean by ASD depends on a number of factors including; the ASD flux into the ocean, its particle size distribution and Fe content. However, none of these parameters are well constrained in the SW Ross Sea region and, as a result, the significance of this Fe source in the biogeochemical cycle of phytoplankton growth remains to be quantified. This study focuses on an area (7400 km²) of Southern McMurdo Sound, one of the few areas where direct sampling of ASD that has accumulated on sea ice is possible. To evaluate the flux and solubility of Fe contained in ASD into McMurdo Sound, the mass accumulation rate and particle size of 70 surface snow samples and 3 shallow (3 m) firn cores from the nearby McMurdo Ice Shelf covering the period 2000 - 2008 have been analysed. Selected samples were also measured for total and soluble Fe, Sr and Nd isotopic ratios and mineralogy as a guide to Fe-fertilisation potential and provenance, respectively. Mass and particle size data show an exponential decrease in mass accumulation rate (from 26.00 g m⁻² yr⁻¹ to 0.70 g m⁻² yr⁻¹) and a decrease in modal particle size (from 130 to 69 μm) over a distance of 120 km from Southern McMurdo Sound northwards to Granite Harbour. Both these trends are consistent with ASD being dispersed northwards across the sea ice by southerly storms from an area of the McMurdo Ice Shelf, where submarine freezing and surface ablation have resulted in a surface covered with debris from the sea floor, known as the 'dirty ice' or 'debris bands' (Lat. 77.929ºS; Long. 165.505ºE) in Southern McMurdo Sound. This assertion is further supported by the Sr and Nd isotopic signature of ASD matching local source rocks and the presence of vesicular glass of Southern McMurdo Sound in all samples which also points to the debris bands as the origin of ASD in McMurdo Sound. Bio-available Fe is extremely difficult to quantify hence Fe solubility was used as an approximation in this thesis. Analysis of both total (i.e. particulate and soluble) and the percentage of soluble Fe in the 0.4 - 10 μm dust size fraction (i.e. the fraction most likely to become bio-available) by solution ICP-MS shows a narrow range of values; 3.84 ± 1.99 wt % and 9.42 ± 0.70 % respectively. Combining these values with mass accumulation rate estimates for the particles 0.4 - 10 μm in size, gives an annual soluble Fe flux for the region 500 km² north of the debris bands in McMurdo Sound of 0.55 mg m⁻² yr⁻¹ (9.89 μmol m⁻² yr⁻¹), with spatial variability largely determined by differences in mass accumulation rate. These fluxes are at least an order of magnitude greater than predicted in global dust deposition models for the Southern Ocean and measured in snow samples from East Antarctica. Furthermore, these values exceed the Fe threshold, estimated as 0.2 nM (Boyd and Abraham, 2001), required for phytoplankton growth following the simple dust-biota model of Boyd et al. (2010) and assuming the release of captured ASD in snow is instantaneous. Whilst not constrained in the present study, ASD sourced from the debris bands may be sufficiently widely dispersed, particularly during storm years, to contribute to Fe-fertilisation up to 1200 km from Southern McMurdo Sound. Short, ~10 year long, firn core records of mass accumulation and methylsuphonate concentration, a proxy for phytoplankton productivity, shows a close correspondence between the two during particularly stormy years. Whilst not demonstrating a cause-and-effect relationship, this observation suggests coastal ice cores may contain an important record of the interplay between climate, dust supply, Fe-fertilisation of near shore waters and phytoplankton productivity on decadal and longer timescales.
format Thesis
author Winton, Victoria Holly Liberty (11686693)
author_facet Winton, Victoria Holly Liberty (11686693)
author_sort Winton, Victoria Holly Liberty (11686693)
title Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica
title_short Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica
title_full Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica
title_fullStr Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica
title_full_unstemmed Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica
title_sort aeolian iron and its contribution to phytoplankton production in mcmurdo sound, southwest ross sea, antarctica
publishDate 2012
url https://doi.org/10.26686/wgtn.16997761.v1
long_lat ENVELOPE(166.500,166.500,-78.000,-78.000)
ENVELOPE(66.067,66.067,-67.867,-67.867)
ENVELOPE(162.733,162.733,-76.883,-76.883)
geographic Southern Ocean
East Antarctica
Ross Sea
McMurdo Sound
McMurdo Ice Shelf
Marsden
Granite Harbour
geographic_facet Southern Ocean
East Antarctica
Ross Sea
McMurdo Sound
McMurdo Ice Shelf
Marsden
Granite Harbour
genre Antarc*
Antarctica
East Antarctica
Ice Shelf
McMurdo Ice Shelf
McMurdo Sound
Ross Sea
Sea ice
Southern Ocean
genre_facet Antarc*
Antarctica
East Antarctica
Ice Shelf
McMurdo Ice Shelf
McMurdo Sound
Ross Sea
Sea ice
Southern Ocean
op_relation https://figshare.com/articles/thesis/Aeolian_Iron_and_Its_Contribution_to_Phytoplankton_Production_in_McMurdo_Sound_Southwest_Ross_Sea_Antarctica/16997761
doi:10.26686/wgtn.16997761.v1
op_rights Author Retains Copyright
op_doi https://doi.org/10.26686/wgtn.16997761.v1
_version_ 1766096873217589248
spelling ftsmithonian:oai:figshare.com:article/16997761 2023-05-15T13:37:42+02:00 Aeolian Iron and Its Contribution to Phytoplankton Production in McMurdo Sound, Southwest Ross Sea, Antarctica Winton, Victoria Holly Liberty (11686693) 2012-01-01T00:00:00Z https://doi.org/10.26686/wgtn.16997761.v1 unknown https://figshare.com/articles/thesis/Aeolian_Iron_and_Its_Contribution_to_Phytoplankton_Production_in_McMurdo_Sound_Southwest_Ross_Sea_Antarctica/16997761 doi:10.26686/wgtn.16997761.v1 Author Retains Copyright Geophysics not elsewhere classified Dust Eolian iron Antarctica Ross Sea McMurdo Sound School: School of Geography Environment and Earth Sciences 040499 Geophysics not elsewhere classified Marsden: 260399 Geochemistry not Elsewhere Classified Marsden: 260402 Chemical Oceanography Marsden: 260602 Climatology (incl. Palaeoclimatology) Marsden: 260104 Sedimentology Degree Discipline: Geology Degree Level: Masters Degree Name: Master of Science Text Thesis 2012 ftsmithonian https://doi.org/10.26686/wgtn.16997761.v1 2021-12-19T22:03:55Z Each summer the waters in McMurdo Sound (Lat. 77.5ºS; Long. 165ºE), south-western (SW) Ross Sea encounter vast phytoplankton blooms. This phenomenon is stimulated by the addition of bio-available iron (Fe) to an environment where phytoplankton growth is otherwise Fe-limited. One possible source of such Fe is aeolian sand and dust (ASD) which accumulates on sea ice and is released into the ocean during the summer melt season. The amount of bio-available Fe (i.e. the amount of Fe immedately accessible to phytoplankton) potentially supplied to the ocean by ASD depends on a number of factors including; the ASD flux into the ocean, its particle size distribution and Fe content. However, none of these parameters are well constrained in the SW Ross Sea region and, as a result, the significance of this Fe source in the biogeochemical cycle of phytoplankton growth remains to be quantified. This study focuses on an area (7400 km²) of Southern McMurdo Sound, one of the few areas where direct sampling of ASD that has accumulated on sea ice is possible. To evaluate the flux and solubility of Fe contained in ASD into McMurdo Sound, the mass accumulation rate and particle size of 70 surface snow samples and 3 shallow (3 m) firn cores from the nearby McMurdo Ice Shelf covering the period 2000 - 2008 have been analysed. Selected samples were also measured for total and soluble Fe, Sr and Nd isotopic ratios and mineralogy as a guide to Fe-fertilisation potential and provenance, respectively. Mass and particle size data show an exponential decrease in mass accumulation rate (from 26.00 g m⁻² yr⁻¹ to 0.70 g m⁻² yr⁻¹) and a decrease in modal particle size (from 130 to 69 μm) over a distance of 120 km from Southern McMurdo Sound northwards to Granite Harbour. Both these trends are consistent with ASD being dispersed northwards across the sea ice by southerly storms from an area of the McMurdo Ice Shelf, where submarine freezing and surface ablation have resulted in a surface covered with debris from the sea floor, known as the 'dirty ice' or 'debris bands' (Lat. 77.929ºS; Long. 165.505ºE) in Southern McMurdo Sound. This assertion is further supported by the Sr and Nd isotopic signature of ASD matching local source rocks and the presence of vesicular glass of Southern McMurdo Sound in all samples which also points to the debris bands as the origin of ASD in McMurdo Sound. Bio-available Fe is extremely difficult to quantify hence Fe solubility was used as an approximation in this thesis. Analysis of both total (i.e. particulate and soluble) and the percentage of soluble Fe in the 0.4 - 10 μm dust size fraction (i.e. the fraction most likely to become bio-available) by solution ICP-MS shows a narrow range of values; 3.84 ± 1.99 wt % and 9.42 ± 0.70 % respectively. Combining these values with mass accumulation rate estimates for the particles 0.4 - 10 μm in size, gives an annual soluble Fe flux for the region 500 km² north of the debris bands in McMurdo Sound of 0.55 mg m⁻² yr⁻¹ (9.89 μmol m⁻² yr⁻¹), with spatial variability largely determined by differences in mass accumulation rate. These fluxes are at least an order of magnitude greater than predicted in global dust deposition models for the Southern Ocean and measured in snow samples from East Antarctica. Furthermore, these values exceed the Fe threshold, estimated as 0.2 nM (Boyd and Abraham, 2001), required for phytoplankton growth following the simple dust-biota model of Boyd et al. (2010) and assuming the release of captured ASD in snow is instantaneous. Whilst not constrained in the present study, ASD sourced from the debris bands may be sufficiently widely dispersed, particularly during storm years, to contribute to Fe-fertilisation up to 1200 km from Southern McMurdo Sound. Short, ~10 year long, firn core records of mass accumulation and methylsuphonate concentration, a proxy for phytoplankton productivity, shows a close correspondence between the two during particularly stormy years. Whilst not demonstrating a cause-and-effect relationship, this observation suggests coastal ice cores may contain an important record of the interplay between climate, dust supply, Fe-fertilisation of near shore waters and phytoplankton productivity on decadal and longer timescales. Thesis Antarc* Antarctica East Antarctica Ice Shelf McMurdo Ice Shelf McMurdo Sound Ross Sea Sea ice Southern Ocean Unknown Southern Ocean East Antarctica Ross Sea McMurdo Sound McMurdo Ice Shelf ENVELOPE(166.500,166.500,-78.000,-78.000) Marsden ENVELOPE(66.067,66.067,-67.867,-67.867) Granite Harbour ENVELOPE(162.733,162.733,-76.883,-76.883)

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