Publications

Bellamy, D; King, J; Nadeau, DF (2025). Mineral dust emissions from proglacial valleys of western Canada: Historical and future dynamics. EARTH SURFACE PROCESSES AND LANDFORMS, 50(5), e70069.

Abstract
Proglacial valleys of the St. Elias Mountains in western Canada are major sources of historical mineral dust emissions, as evidenced through loess records, yet no estimates of contemporary emissions exist for this region. In these landscapes, dust emissions occur at the interface of glaciofluvial and aeolian processes, not only subject to large seasonal-annual variability but facing major near-future changes following rapid deglaciation. We present a camera-derived observational record of dust emission activity in the A'& aogon;y Ch & ugrave; (Yukon, Canada; 60.94 degrees N 138.63 degrees W) and adjacent proglacial valleys between 2016 and 2022, immediately following a major glacial drainage reorganisation. In the A'& aogon;y Ch & ugrave; valley, we observe between 57 and 99 days of dust activity per year. Using Landsat 5-8 and MODIS retrievals, long-term variability in water, snow cover and NDVI was constrained from 1984 to 2023. Across four proglacial valleys, we identify 77.6 km2 of erodible area (58% of watercourse area), prone to frequent transient meltwater inundation, exposure and potential deflation of glacigenic sediments. Significant variability in seasonal surface erodibility exists between valleys, made notable following the migration of sediment stores into adjacent valleys prone to prolonged snow cover. Ongoing glacier recession and warming climates are anticipated to yield a transient increase in erodible area, and likely dust emissions, in the region over the next several decades. The subsequent decline is anticipated with further deglaciation and the continuing paraglacial transition of proglacial landscapes. A conceptual model is presented to this effect. Understanding contemporary dust emission sources, emission activity and near-future changes in emission dynamics is critical to establish the role regional mineral dust emissions will occupy in local climatic forcing over the coming decades.

DOI:
10.1002/esp.70069

ISSN:
1096-9837