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An improved ocean model of aluminium: the effects of circulation, sediment resuspension and biological incorporation (2013)

van Hulten, M. M. P. ; Sterl, A. ; Middag, R. ; [et al.]

Copernicus

In: Biogeosciences Discussions. 2013; 10(9): 14539-14593. Published 2013 Sep 02. doi: 10.5194/bgd-10-14539-2013.

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Publication Date: 2013-09-02

Description: The distribution of dissolved aluminium (Al) in the ocean is of interest because of its potential impact on diatom remineralisation and the use of surface ocean Al as a tracer for dust. Previously, the ocean Al concentration has been simulated reasonably well with only a dust source and scavenging as the removal process. In this study the simulation has been significantly improved by a more refined circulation and the addition of a sediment resuspension source. The latter confirms that the most significant sources of Al to the ocean are dust deposition and sediment resuspension. Simulations with biological incorporation have been performed as well. These show that this can be an important removal process. However, this study does not provide a definitive answer to the question what the relative amount of incorporation is compared to scavenging.

Print ISSN: 1810-6277

Electronic ISSN: 1810-6285

Topics: Biology , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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On the effects of circulation, sediment resuspension and biological incorporation by diatoms in an ocean model of aluminium* (2014)

van Hulten, M. M. P. ; Sterl, A. ; Middag, R. ; [et al.]

Copernicus

In: Biogeosciences. 2014; 11(14): 3757-3779. Published 2014 Jul 18. doi: 10.5194/bg-11-3757-2014.

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Publication Date: 2014-07-18

Description: The distribution of dissolved aluminium in the West Atlantic Ocean shows a mirror image with that of dissolved silicic acid, hinting at intricate interactions between the ocean cycling of Al and Si. The marine biogeochemistry of Al is of interest because of its potential impact on diatom opal remineralisation, hence Si availability. Furthermore, the dissolved Al concentration at the surface ocean has been used as a tracer for dust input, dust being the most important source of the bio-essential trace element iron to the ocean. Previously, the dissolved concentration of Al was simulated reasonably well with only a dust source, and scavenging by adsorption on settling biogenic debris as the only removal process. Here we explore the impacts of (i) a sediment source of Al in the Northern Hemisphere (especially north of ~ 40° N), (ii) the imposed velocity field, and (iii) biological incorporation of Al on the modelled Al distribution in the ocean. The sediment source clearly improves the model results, and using a different velocity field shows the importance of advection on the simulated Al distribution. Biological incorporation appears to be a potentially important removal process. However, conclusive independent data to constrain the Al / Si incorporation ratio by growing diatoms are missing. Therefore, this study does not provide a definitive answer to the question of the relative importance of Al removal by incorporation compared to removal by adsorptive scavenging.

Print ISSN: 1726-4170

Electronic ISSN: 1726-4189

Topics: Biology , Geosciences

Published by Copernicus on behalf of European Geosciences Union.

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Trace element and isotope deposition across the air–sea interface: progress and research needs (2016)

Baker, A. R. ; Landing, W. M. ; Bucciarelli, E. ; [et al.]

The Royal Society

In: Philosophical Transactions of the Royal Society of London. Series A, Mathematical, Physical and Engineering Sciences. 2016; 374(2081): 20160190. Published 2016 Nov 28. doi: 10.1098/rsta.2016.0190.

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Publication Date: 2016-11-28

Description: The importance of the atmospheric deposition of biologically essential trace elements, especially iron, is widely recognized, as are the difficulties of accurately quantifying the rates of trace element wet and dry deposition and their fractional solubility. This paper summarizes some of the recent progress in this field, particularly that driven by the GEOTRACES, and other, international research programmes. The utility and limitations of models used to estimate atmospheric deposition flux, for example, from the surface ocean distribution of tracers such as dissolved aluminium, are discussed and a relatively new technique for quantifying atmospheric deposition using the short-lived radionuclide beryllium-7 is highlighted. It is proposed that this field will advance more rapidly by using a multi-tracer approach, and that aerosol deposition models should be ground-truthed against observed aerosol concentration data. It is also important to improve our understanding of the mechanisms and rates that control the fractional solubility of these tracers. Aerosol provenance and chemistry (humidity, acidity and organic ligand characteristics) play important roles in governing tracer solubility. Many of these factors are likely to be influenced by changes in atmospheric composition in the future. Intercalibration exercises for aerosol chemistry and fractional solubility are an essential component of the GEOTRACES programme. This article is part of the themed issue ‘Biological and climatic impacts of ocean trace element chemistry’.

Print ISSN: 1364-503X

Electronic ISSN: 1471-2962

Topics: Mathematics , Physics , Technology

Published by The Royal Society

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Modelling the role of marine particle on large scale 231Pa, 230Th, Iron and Aluminium distributions (2015)

Dutay, J.-C. ; Tagliabue, A. ; Kriest, Iris ; [et al.]

Elsevier

In: Progress in Oceanography, 133 . pp. 66-72.

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Publication Date: 2019-09-23

Description: Highlights: • We examine the role of marine particle for regulating trace element distribution. • We review the state of the art for modelling the oceanic distribution of specific tracers: Thorium, Protactinium, Iron, and Aluminium. • We review the state of the art for modelling particle distribution in large scale ocean biogeochemical model. The distribution of trace elements in the ocean is governed by the combined effects of various processes, and by exchanges with external sources. Modelling these represents an opportunity to better understand and quantify the mechanisms that regulate the oceanic tracer cycles. Observations collected during the GEOTRACES program provide an opportunity to improve our knowledge regarding processes that should be considered in biogeochemical models to adequately represent the distributions of trace elements in the ocean. Here we present a synthesis about the state of the art for simulating selected trace elements in biogeochemical models: Protactinium, Thorium, Iron and Aluminium. In this contribution we pay particular attention on the role of particles in the cycling of these tracers and how they may provide additional constraints on the transfer of matter in the ocean.

Type: Article , PeerReviewed

Format: text

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Trace element and isotope deposition across the air–sea interface: progress and research needs (2016)

Baker, A. R. ; Landing, W. M. ; Bucciarelli, E. ; [et al.]

The Royal Society

In: Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 374 (2081). p. 20160190.

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Publication Date: 2019-02-01

Description: The importance of the atmospheric deposition of biologically essential trace elements, especially iron, is widely recognized, as are the difficulties of accurately quantifying the rates of trace element wet and dry deposition and their fractional solubility. This paper summarizes some of the recent progress in this field, particularly that driven by the GEOTRACES, and other, international research programmes. The utility and limitations of models used to estimate atmospheric deposition flux, for example, from the surface ocean distribution of tracers such as dissolved aluminium, are discussed and a relatively new technique for quantifying atmospheric deposition using the short-lived radionuclide beryllium-7 is highlighted. It is proposed that this field will advance more rapidly by using a multi-tracer approach, and that aerosol deposition models should be ground-truthed against observed aerosol concentration data. It is also important to improve our understanding of the mechanisms and rates that control the fractional solubility of these tracers. Aerosol provenance and chemistry (humidity, acidity and organic ligand characteristics) play important roles in governing tracer solubility. Many of these factors are likely to be influenced by changes in atmospheric composition in the future. Intercalibration exercises for aerosol chemistry and fractional solubility are an essential component of the GEOTRACES programme. This article is part of the themed issue 'Biological and climatic impacts of ocean trace element chemistry'.

Type: Article , PeerReviewed

Format: text

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