Abstract
The mass loss of the Greenland Ice Sheet is nearly equally partitioned between a decrease in surface mass balance from enhanced surface melt and an increase in ice dynamics from the acceleration and retreat of its marine-terminating glaciers. Much uncertainty remains in the future mass loss of the Greenland Ice Sheet due to the challenges of capturing the ice dynamic response to climate change in numerical models. Here, we estimate the sea level contribution of the Greenland Ice Sheet over the 21st century using an ice-sheet wide, high-resolution, ice-ocean numerical model that includes surface mass balance forcing, thermal forcing from the ocean, and iceberg calving dynamics. The model is calibrated with ice front observations from the past eleven years to capture the recent evolution of marine-terminating glaciers. Under a business as usual scenario, we find that northwest and central west Greenland glaciers will contribute more mass loss than other regions due to ice front retreat and ice flow acceleration. By the end of century, ice discharge from marine-terminating glaciers will contribute 50 ± 20% of the total mass loss, or twice as much as previously estimated although the contribution from the surface mass balance increases towards the end of the century.
Highlights
The mass loss of the Greenland Ice Sheet is nearly partitioned between a decrease in surface mass balance from enhanced surface melt and an increase in ice dynamics from the acceleration and retreat of its marine-terminating glaciers
The increase in melting at the ice sheet surface has been accounting for a large share of this mass loss in recent years, glacier dynamics has been responsible for 66% of the total mass loss over the last 46 years[1]
We projected the future sea-level contribution of Greenland with a high-resolution model that accounts for changes in ice front of individual marine-terminating glaciers, iceberg calving dynamics, and thermal forcing from the ocean
Summary
The mass loss of the Greenland Ice Sheet is nearly partitioned between a decrease in surface mass balance from enhanced surface melt and an increase in ice dynamics from the acceleration and retreat of its marine-terminating glaciers. Several studies have been dedicated to projecting the future sea level contribution of Greenland with a focus on glacier dynamics[11,12,13,14] While these studies include modeled changes in surface mass balance (SMB), they often use a coarse grid resolution or simplified physics, and do not calibrate their models at the glacier scale and with decades of observations. We run the model forward from 2007 to 2017 and calibrate the calving parameterization for each glacier drainage basin so that the model is consistent with observed velocities, changes in ice front positions, and ice thinning rates (see “Methods”) This calibration process captures the current state of the ice sheet and the trend in mass loss for the first decade, which improves its reliability for short-term projections[17]. Contrary to the data provided by ISMIP6, we use a temporal resolution of one month for these climatic forcings, instead of one year, to capture the seasonal cycle in SMB and ocean temperatures, which is important in the context of glacier de-stabilization[22,23]
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