Annual and seasonal variability in high latitude dust deposition, West Greenland

High latitude regions (≥ 50°N and ≥ 40°S) are thought to contribute substantially to contemporary global dust emissions which can influence biogeochemical cycling as well as geomorphic, cryospheric and atmospheric processes. However, there are few measurements of the emission or deposition of dust d...

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Bibliographic Details
Published in:Earth surface processes and landforms 2022-08, Vol.47 (10), p.2393-2409
Main Authors: Soest, Maud A. J., Bullard, Joanna E., Prater, Clay, Baddock, Matthew C., Anderson, N. John
Format: Article
Language:English
Subjects:
aeolian
Annual variations
Arctic
Atmospheric particulates
Atmospheric processes
Deposition
Dust
dust codes
Dust cycle
Dust deposition
Emission measurements
Emissions
Geomorphology
Glacial deposits
Glacial outwash
Latitude
loess
Meltwater
Outwash
proglacial
Seasonal variability
Seasonal variation
Seasonal variations
Seasons
Sediment
Sediments
Spring
Spring (season)
Visibility
Wind speed
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Summary:High latitude regions (≥ 50°N and ≥ 40°S) are thought to contribute substantially to contemporary global dust emissions which can influence biogeochemical cycling as well as geomorphic, cryospheric and atmospheric processes. However, there are few measurements of the emission or deposition of dust derived from these areas that extend beyond a single event or season. This article reports the deposition of locally‐derived dust to an ice‐free area of West Greenland over 2 years from 23 traps distributed across five sampling sites. Local dust sources include glacial outwash plains, glacially‐derived delta deposits and the reworking of loessic soils. Annual dust deposition is estimated at 37.3 to 93.9 g m−2 for 2017–2018 and 9.74 to 28.4 g m−2 in 2018–2019. This annual variation is driven by high deposition rates observed in spring 2017 of 0.48 g m−2 d−1 compared to the range of 0.03 to 0.07 g m−2 d−1 during the rest of the monitoring period. The high deposition rates in spring 2017 were due to warmer than average conditions and high meltwater sediment supply that delivered large quantities of sediment to local outwash plains in 2016. For other seasons, dust deposition was lower over both autumn–winter periods (0.03 g m−2 d−1) than during the spring and summer (0.04–0.07 g m−2 d−1). When sediment availability is limited, dust deposition increases with increasing temperature and wind speed. Secondary data from dust‐related weather type/observation codes and visibility records were found to be inconsistent with measured dust deposition during the period of study. One possible reason for this is the complex nature of the terrain between the observation and sample sites. The dust deposition rates measured here and the infidelity of the observed dust with secondary data sources reveal the importance of direct quantification of dust processes to accurately constrain the dust cycle at high latitudes. Dust originating within high latitude regions contributes to the contemporary global dust cycle. Measurements at five sites in West Greenland indicate rates of local dust deposition have high seasonal and interannual variability linked to sediment supply and meteorological conditions. Secondary meteorological records of dustiness are not consistent with field measurements at this location.
ISSN:0197-9337
1096-9837
DOI:10.1002/esp.5384