Iron speciation in aerosol dust influences iron bioavailability over glacial-interglacial timescales

A. Spolaor; Paul Travis Vallelonga; G. Gozzi; J. Gabrieli; C. Varin; N. Kehewald; P. Zennaro; C. Boutron; C. Barbante

doi:10.1002/grl.50296

Iron speciation in aerosol dust influences iron bioavailability over glacial-interglacial timescales

A. Spolaor, Paul Travis Vallelonga, G. Gozzi, J. Gabrieli, C. Varin, N. Kehewald, P. Zennaro, C. Boutron, C. Barbante

Is-, Klima- og Geofysik

23 Citationer (Scopus)

Abstract

Iron deposition influences primary production and oceanic sequestration of atmospheric carbon dioxide (CO₂). Iron has two oxidation states, Fe(II) and Fe(III), with Fe(II) being more soluble and available for oceanic phytoplankton uptake. The past proportions of soluble iron in aerosol dust remain unknown. Here we present iron speciation (Fe²⁺ and Fe ³⁺) in the Antarctic Talos Dome ice core over millennial time scales. We demonstrate that iron speciation over the last 55 kyr is linked to increasing quantities of fine dust (FD) (0.7-5 μm) and intensified long-range dust transport. We propose that Fe(II) and Fe²⁺ production is principally enhanced in FD by photoreduction, although pH and organic complexation may also contribute to the speciation dynamics. During the Last Glacial Maximum, Fe²⁺ concentrations in dust increased by up to seven times more than interglacial levels, while Fe³⁺ only doubled. Cold and dusty climatic periods may increase the percentage of biologically available Fe(II) and Fe²⁺ deposited in the nutrient-limited Southern Ocean, allowing greater phytoplankton uptake and perhaps increased CO₂ drawdown. Key Points The first work recording iron speciation in ice core in glacial-interglacial Importance of iron species in the bioavailability of iron It demonstrates that the addition of iron species results in CO2 drawdown.

Originalsprog	Engelsk
Tidsskrift	Geophysical Research Letters
Vol/bind	40
Udgave nummer	8
Sider (fra-til)	1618-1623
ISSN	0094-8276
DOI	https://doi.org/10.1002/grl.50296
Status	Udgivet - 28 apr. 2013

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10.1002/grl.50296

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title = "Iron speciation in aerosol dust influences iron bioavailability over glacial-interglacial timescales",

abstract = "Iron deposition influences primary production and oceanic sequestration of atmospheric carbon dioxide (CO2). Iron has two oxidation states, Fe(II) and Fe(III), with Fe(II) being more soluble and available for oceanic phytoplankton uptake. The past proportions of soluble iron in aerosol dust remain unknown. Here we present iron speciation (Fe2+ and Fe 3+) in the Antarctic Talos Dome ice core over millennial time scales. We demonstrate that iron speciation over the last 55 kyr is linked to increasing quantities of fine dust (FD) (0.7-5 μm) and intensified long-range dust transport. We propose that Fe(II) and Fe2+ production is principally enhanced in FD by photoreduction, although pH and organic complexation may also contribute to the speciation dynamics. During the Last Glacial Maximum, Fe2+ concentrations in dust increased by up to seven times more than interglacial levels, while Fe3+ only doubled. Cold and dusty climatic periods may increase the percentage of biologically available Fe(II) and Fe2+ deposited in the nutrient-limited Southern Ocean, allowing greater phytoplankton uptake and perhaps increased CO2 drawdown. Key Points The first work recording iron speciation in ice core in glacial-interglacial Importance of iron species in the bioavailability of iron It demonstrates that the addition of iron species results in CO2 drawdown.",

author = "A. Spolaor and Vallelonga, {Paul Travis} and G. Gozzi and J. Gabrieli and C. Varin and N. Kehewald and P. Zennaro and C. Boutron and C. Barbante",

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T1 - Iron speciation in aerosol dust influences iron bioavailability over glacial-interglacial timescales

AU - Spolaor, A.

AU - Vallelonga, Paul Travis

AU - Gozzi, G.

AU - Gabrieli, J.

AU - Varin, C.

AU - Kehewald, N.

AU - Zennaro, P.

AU - Boutron, C.

AU - Barbante, C.

PY - 2013/4/28

Y1 - 2013/4/28

N2 - Iron deposition influences primary production and oceanic sequestration of atmospheric carbon dioxide (CO2). Iron has two oxidation states, Fe(II) and Fe(III), with Fe(II) being more soluble and available for oceanic phytoplankton uptake. The past proportions of soluble iron in aerosol dust remain unknown. Here we present iron speciation (Fe2+ and Fe 3+) in the Antarctic Talos Dome ice core over millennial time scales. We demonstrate that iron speciation over the last 55 kyr is linked to increasing quantities of fine dust (FD) (0.7-5 μm) and intensified long-range dust transport. We propose that Fe(II) and Fe2+ production is principally enhanced in FD by photoreduction, although pH and organic complexation may also contribute to the speciation dynamics. During the Last Glacial Maximum, Fe2+ concentrations in dust increased by up to seven times more than interglacial levels, while Fe3+ only doubled. Cold and dusty climatic periods may increase the percentage of biologically available Fe(II) and Fe2+ deposited in the nutrient-limited Southern Ocean, allowing greater phytoplankton uptake and perhaps increased CO2 drawdown. Key Points The first work recording iron speciation in ice core in glacial-interglacial Importance of iron species in the bioavailability of iron It demonstrates that the addition of iron species results in CO2 drawdown.

AB - Iron deposition influences primary production and oceanic sequestration of atmospheric carbon dioxide (CO2). Iron has two oxidation states, Fe(II) and Fe(III), with Fe(II) being more soluble and available for oceanic phytoplankton uptake. The past proportions of soluble iron in aerosol dust remain unknown. Here we present iron speciation (Fe2+ and Fe 3+) in the Antarctic Talos Dome ice core over millennial time scales. We demonstrate that iron speciation over the last 55 kyr is linked to increasing quantities of fine dust (FD) (0.7-5 μm) and intensified long-range dust transport. We propose that Fe(II) and Fe2+ production is principally enhanced in FD by photoreduction, although pH and organic complexation may also contribute to the speciation dynamics. During the Last Glacial Maximum, Fe2+ concentrations in dust increased by up to seven times more than interglacial levels, while Fe3+ only doubled. Cold and dusty climatic periods may increase the percentage of biologically available Fe(II) and Fe2+ deposited in the nutrient-limited Southern Ocean, allowing greater phytoplankton uptake and perhaps increased CO2 drawdown. Key Points The first work recording iron speciation in ice core in glacial-interglacial Importance of iron species in the bioavailability of iron It demonstrates that the addition of iron species results in CO2 drawdown.

U2 - 10.1002/grl.50296

DO - 10.1002/grl.50296

M3 - Journal article

SN - 0094-8276

VL - 40

SP - 1618

EP - 1623

JO - Geophysical Research Letters

JF - Geophysical Research Letters

IS - 8

ER -

Iron speciation in aerosol dust influences iron bioavailability over glacial-interglacial timescales

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