Abstract
Massive amounts of Saharan dust are blown from the coast of northern Africa
across the Atlantic Ocean towards the Americas each year. This dust has,
depending on its chemistry, direct and indirect effects on global climate
which include reflection and absorption of solar radiation as well as transport
and deposition of nutrients and metals fertilizing both ocean and land. To
determine the temporal and spatial variability of Saharan dust transport and
deposition and their marine environmental effects across the equatorial North
Atlantic Ocean, we have set up a monitoring experiment using deep-ocean
sediment traps as well as land-based dust collectors. The sediment traps were
deployed at five ocean sites along a transatlantic transect between north-west
Africa and the Caribbean along 12° N, in a downwind extension of
the land-based dust collectors placed at 19° N on the Mauritanian
coast in Iouîk. In this paper, we lay out the setup of the monitoring
experiment and present the particle fluxes from sediment trap sampling over
24 continuous and synchronized intervals from October 2012 through to
November 2013. We establish the temporal distribution of the particle fluxes
deposited in the Atlantic and compare chemical compositions with the
land-based dust collectors propagating to the downwind sediment trap sites,
and with satellite observations of Saharan dust outbreaks.
First-year results show that the total mass fluxes in the ocean are highest
at the sampling sites in the east and west, closest to the African continent
and the Caribbean, respectively. Element ratios reveal that the lithogenic
particles deposited nearest to Africa are most similar in composition to the
Saharan dust collected in Iouîk. Downwind increasing Al, Fe and K contents
suggest a downwind change in the mineralogical composition of Saharan dust
and indicate an increasing contribution of clay minerals towards the west. In
the westernmost Atlantic Ocean, admixture of re-suspended clay-sized
sediments advected towards the deep sediment trap cannot be excluded.
Seasonality is most prominent near both continents but generally weak, with
mass fluxes dominated by calcium carbonate and clear seasonal maxima of
biogenic silica towards the west. The monitoring experiment is now extended,
with autonomous dust sampling buoys for better quantification of Saharan dust
transport and deposition from source to sink and their impact on fertilization
and carbon export to the deep ocean.
Citation
ID:
204784
Ref Key:
korte2017atmosphericdownward