1. Global Warming Threshold and Mechanisms for Accelerated Greenland Ice Sheet Surface Mass Loss.
- Author
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Sellevold, Raymond and Vizcaíno, Miren
- Subjects
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GREENLAND ice , *ICE sheets , *GLOBAL warming , *NORTH Atlantic oscillation , *ATMOSPHERIC temperature - Abstract
The Community Earth System Model version 2.1 (CESM2.1) is used to investigate the evolution of the Greenland ice sheet (GrIS) surface mass balance (SMB) under an idealized CO2 forcing scenario of 1% increase until stabilization at 4× pre‐industrial at model year 140. In this simulation, the SMB calculation is coupled with the atmospheric model, using a physically based surface energy balance scheme for melt, explicit calculation of snow albedo, and a realistic treatment of polar snow and firn compaction. By the end of the simulation (years 131–150), the SMB decreases with 994 Gt yr−1 with respect to the pre‐industrial SMB, which represents a sea‐level rise contribution of 2.8 mm yr−1. For a threshold of 2.7‐K global temperature increase with respect to pre‐industrial, the rate of expansion of the ablation area increases, the mass loss accelerates due to loss of refreezing capacity and accelerated melt, and the SMB becomes negative 6 years later. Before acceleration, longwave radiation is the most important contributor to increasing energy for melt. After acceleration, the large expansion of the ablation area strongly reduces surface albedo. This and much increased turbulent heat fluxes as the GrIS‐integrated summer surface temperature approaches melt point become the major sources of energy for melt. Plain Language Summary: The Greenland ice sheet (GrIS) is the largest freshwater reservoir in the Northern Hemisphere, with the potential of raising sea levels with 7.1 m if fully melted. Here, we investigate the evolution of the GrIS under elevated levels of CO2 in a model with an advanced and coupled surface mass balance (SMB; the difference between mass gain and mass loss at the ice sheet surface) calculation. By the end of our simulation, the global mean temperature increases with 5.3 K, contributing to a sea‐level rise rate of 2.8 mm yr−1 from the GrIS surface. At a global temperature increase of 2.7 K, the rate of mass loss from the GrIS accelerates due to a darker ice sheet surface and much increased atmospheric temperatures over the GrIS. Key Points: GrIS surface mass loss accelerates for a global warming of 2.7 K through increased surface melt and loss of refreezing capacityLongwave radiation is the main contributor to melt increase before acceleration; albedo and turbulent fluxes add major contributions afterAnthropogenic‐forced atmospheric circulation changes (North Atlantic Oscillation and Greenland blocking index) partially reduce melt [ABSTRACT FROM AUTHOR]
- Published
- 2020
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