Seasonal and interannual variabilities in terminus position, glacier velocity, and surface elevation at Helheim and Kangerlussuaq Glaciers from 2008 to 2016

146

Seasonal glacier ice velocities are important for understanding controlling mechanisms of ice flow. For many Greenlandic glaciers, however, these measurements are limited by low temporal resolution. We present seasonal ice velocity changes, melt season onset and extent, and ice front positions for 45 Greenlandic glaciers using 2015–2017 Sentinel‐1 synthetic aperture radar data. Seasonal velocity fluctuations of roughly half of the glaciers appear to be primarily controlled by surface melt‐induced changes in the subglacial hydrology. This includes (1) glaciers that speed up with the onset of surface melt and (2) glaciers with comparable late winter and early melt season velocities that show significant slowdown during most of the melt season and speedup during winter. In contrast, less than a quarter of the study glaciers show strong correspondence between seasonal ice speed and terminus changes. Our results pinpoint seasonal variations across Greenland, highlighting the variable influence of meltwater on year‐round ice velocities.

Section: Discussionmentioning

confidence: 83%

Section: Introductionmentioning

confidence: 90%

See 1 more Smart Citation

Resolving Seasonal Ice Velocity of 45 Greenlandic Glaciers With Very High Temporal Details

Vijay

Khan

Kusk

et al. 2019

146

“…Many tidewater glaciers and ice streams show periodic summer speedups (e.g., Dunse et al, 2015;Kehrl et al, 2017;Neckel et al, 2016;Schellenberger et al, 2017;Sevestre et al, 2018). This is due to seasonal variation in subglacial hydrology that greatly affects the glacier sliding speeds (Sevestre et al, 2018).…”

Section: Summer Speedup Eventsmentioning

confidence: 99%

The Possible Transition From Glacial Surge to Ice Stream on Vavilov Ice Cap

Zheng

Pritchard

Willis

et al. 2019

Surge-type glaciers typically undergo cyclical flow instability due to mass accumulation; however, some recent glacier surges have caused irreversible ice loss in a short period. At Vavilov Ice Cap, Russia, surge-like behavior initiated in 2013 and by spring 2019 the ice cap had lost 9.5 Gt of ice (11% mass of the entire basin). Using time series of surface elevation and glacier velocity derived from satellite optical and synthetic-aperture radar imagery, we identify a shift of flow pattern starting in 2017 when shear margins formed within the grounded marine piedmont fan. Multiple summer speedups correlate with warmer summers during 2015-2019 and suggest that surface melt may access the subglacial environment. Force balance analysis and examination of the Péclet number show that glacier thinning propagated upstream in 2016-2017, and diffusion became a significant dynamic response to thinning perturbations. Our results suggest that the glacier has entered a new ice stream-like regime. Plain Language SummaryA glacier surge is a sudden speedup of glacier flow coinciding with a large advance of the ice front. Some glaciers surge periodically every 10-100 years, and so surge mechanism is thought to be independent of climate change. However, some recent surges have evacuated so much ice that another surge is unlikely to occur in the same place again. A glacier surge at the Vavilov Ice Cap, Russia, is one of these cases. Since 2013, the glacier has drained more than 11% of the ice basin (9.5 Gt) into the ocean. After the initial surge in 2013, the glacier still retains fast flow at around 1.8 km/year, an unusually high and long-lasting speed for a glacier surge. To understand the future of the surge, we use satellite images to calculate surface elevations and ice speeds, and analyze their change over time for the glacier. The results reveal that the glacier now physically behaves more like an "ice stream," a stream of fast-flowing ice within an ice sheet, which can probably flow at high speed for a long time and drain ice efficiently. This is the first documented case of an ice stream-like feature ever being formed.

“…Several hypotheses have been proposed to explain the variability in glacier response to climate warming, including differences in glacier/fjord geometry (Felikson et al, 2017;Kehrl et al, 2017;Meier & Post, 1987;Porter et al, 2014), atmospheric warming (Moon & Joughin, 2008), subglacial discharge (Bartholomaus et al, 2016;Motyka et al, 2013;Xu et al, 2013), and ocean-induced melting (Larsen et al, 2016;Rignot et al, 2010Rignot et al, , 2016. These analyses suggest a complex interplay between bed topography, enhanced runoff due to atmospheric warming, enhanced ocean-induced ice melt due to ocean warming, and the supply of ice from upstream.…”

Section: Introductionmentioning

confidence: 99%

Ocean‐Induced Melt Triggers Glacier Retreat in Northwest Greenland

Wood

Rignot

Fenty

et al. 2018

In recent decades, tidewater glaciers in Northwest Greenland contributed significantly to sea level rise but exhibited a complex spatial pattern of retreat. Here we use novel observations of bathymetry and water temperature from NASA's Ocean Melting Greenland mission to quantify the role of warm, salty Atlantic Water in controlling the evolution of 37 glaciers. Modeled ocean‐induced undercutting of calving margins compared with ice advection and ice front retreat observed by satellites from 1985 to 2015 indicate that 35 glaciers retreated when cumulative anomalies in ocean‐induced undercutting rose above the range of seasonal variability of calving‐front positions, while two glaciers standing on shallow sills and colder water did not retreat. Deviations in the observed timing of retreat are explained by residual uncertainties in bathymetry, inefficient mixing of waters in shallow fjords, and the presence of small floating sections. Overall, warmer ocean temperature triggered the retreat, but calving processes dominate ablation (71%).