Particulate iron and other trace elements in near-surface waters of the high latitude North Atlantic following the 2010 Eyjafjallajökull eruption

In situ pumps were used to collect size-fractionated particles (>53 μm and 1–53 μm) from the upper ocean of the high latitude North Atlantic during spring and summer 2010, and samples were subsequently analysed for Al, P, Ti, V, Mn, Fe, Co, Ni, Cu, Zn, Cd, Ba and Pb. Two research cruises during May 2010 coincided with an eruption of the Eyjafjallajökull volcano in southern Iceland, which resulted in widespread dispersal of ash over the region. Ash deposition caused a noticeable perturbation of particulate trace element concentrations and content within marine particles in the Iceland Basin, relative to the Irminger Basin, most evident for lithogenic elements (Al, Ti, Fe), but also noticeable in elemental ratios for the other elements. The initial volcanic ash influence had largely disappeared by the third research cruise in July/August 2010, although there was evidence for a recent wind erosion event having transported remobilized volcanic ash from southern Iceland to the northern Iceland Basin in early July, further perturbing local trace element biogeochemistry. During summer 2010, concentrations of all measured elements except Ba were typically lower 10 m beneath the surface mixed layer relative to those within it, driven primarily by a rapid decrease in the concentrations of large (>53 μm) biogenic particles. Depth-dependent trends were more variable over the next hundred metres for all elements except the biogenic elements P and Cd, for which concentrations decreased further. The continued loss of biogenic material with depth due to remineralization (reflected by particulate P concentrations) led to an increase in content per mass of material for all other elements measured. The observed differences in upper ocean particulate P and Fe distributions highlight the mechanism driving seasonal Fe limitation in the high latitude North Atlantic: rapid loss of P by remineralization regenerates dissolved phosphate close to the base of the mixed layer, while most particulate Fe persists deeper in the water column, removing the potential for resupply of dissolved Fe to surface waters.

Chemical composition, Eyjafjallajökull, Iceland Basin, Irminger Basin, Suspended particulate matter, Trace elements, Volcanic ash

10.1016/j.marchem.2021.103959

0304-4203

103959

Marsay, Chris M.

f18098e4-e58c-4799-a7fc-5d6f8ec95677

Achterberg, Eric P.

685ce961-8c45-4503-9f03-50f6561202b9

20 May 2021

Marsay, Chris M.

f18098e4-e58c-4799-a7fc-5d6f8ec95677

Achterberg, Eric P.

685ce961-8c45-4503-9f03-50f6561202b9

Marsay, Chris M. and Achterberg, Eric P. (2021) Particulate iron and other trace elements in near-surface waters of the high latitude North Atlantic following the 2010 Eyjafjallajökull eruption. Marine Chemistry, 232, 103959, [103959]. (doi:10.1016/j.marchem.2021.103959).

Record type: Article

Abstract

Text

Particulate iron and other trace elements

Restricted to Repository staff only

Available under License Creative Commons Attribution Non-commercial No Derivatives.

Request a copy

More information

Accepted/In Press date: 4 February 2021

Published date: 20 May 2021

Additional Information: Funding Information: We thank all the scientists and crew members who worked together on RRS Discovery research cruises D350, D351 and D354, and in particular Frederic Le Moigne and Maria Villa-Alfageme, who helped with SAPS deployments during D350/D354 and Sebastian Steigenberger who did so during D351. We also acknowledge the ICPMS assistance from Dr. Andy Milton at National Oceanography Centre Southampton. This work was funded by Natural Environment Research Council (UK) grant NE/E006833/1 , awarded to E.A. and C. Mark Moore, and by a National Oceanography Centre Southampton studentship to C.M.M. Publisher Copyright: © 2021 Elsevier B.V.

Keywords: Chemical composition, Eyjafjallajökull, Iceland Basin, Irminger Basin, Suspended particulate matter, Trace elements, Volcanic ash