Zahn, M., Laidre, K.L., Simon, K., Stafford, K., Wood, M., Willis, J.K., Phillips, E.M., and Fenty, I.G. (2024)
Presented at:
Ocean Sciences Meeting 2024Greenland's marine-terminating glaciers connect the ice sheet to the ocean and provide a critical boundary where heat, freshwater, and nutrient exchanges take place. Buoyant freshwater runoff from inland ice sheet melt is discharged at the base of marine-terminating glaciers, forming a vigorous upwelling plume. It is understood that subglacial plumes modify waters near glacier fronts and increase submarine glacier melt by entraining warm ambient waters at depth. However, ocean observations along Greenland's coastal margins remain biased toward summer months which limits accurate estimation of ocean forcing on glacier retreat and acceleration. Here, we fill a key observational gap in northwest Greenland by describing seasonal hydrographic variation at glacier fronts in Melville Bay using in situ observations from moorings, CTDs, and profiling floats. We evaluated local and remote forcing using remote sensing and reanalysis data products alongside a high resolution ocean model. Analysis of the year-round hydrographic data revealed consistent above-sill seasonality in temperature and salinity with site-specific plume signatures determined by glacier depth and runoff rate. The warmest, saltiest waters occurred in the spring (April-May) and primed glaciers for enhanced submarine melt in summer when meltwater plumes entrain deep waters. Waters were coldest and freshest in early winter (November-December) after summer sea ice and glacier melt provided cold freshwater input along the shelf. Ocean variability was greatest in the fall, coincident with large storms and wind events before sea ice formation. Results from this work increase our mechanistic understanding of Greenland ice-ocean interactions and enable improvements in ocean model parameterization.