Abstract
Abstract. A transient technique for generating ice sheet preindustrial initial conditions for long-term coupled ice sheet/climate model simulations is developed and demonstrated over the Greenland ice sheet using the Community Earth System Model (CESM). End-member paleoclimate simulations of the last glacial maximum, mid-Holocene optimum and the preindustrial are combined using weighting provided by ice core data time series to derive continuous energy-balance-model-derived surface mass balance and surface temperature fields, which are subsequently used to force a long transient ice sheet model simulation of the last glacial cycle, ending at the preindustrial. The procedure accounts for the evolution of climate through the last glacial period and converges to a simulated preindustrial ice sheet that is geometrically and thermodynamically consistent with the preindustrial CESM state, yet contains a transient memory of past climate. The preindustrial state generated using this technique notably improves upon the standard equilibrium spin-up technique, relative to observations and other model studies, although in the demonstration we present here, large biases remain due primarily to climate model forcing biases. Ultimately, the method we describe provides a clear template for generating initial conditions for ice sheets within a fully coupled climate model framework that allows for the effects of past climate history to be self-consistently included in long-term simulations of the fully coupled ice sheet/climate system.
Highlights
Ice sheets play an important role in regulating critical aspects of the climate system such as sea level rise (Foster and Rohling, 2013), atmospheric circulation (Ridley et al, 2005) and ocean circulation (Weaver et al, 2003)
The significant novelty of the present procedure is that it extends these techniques by utilizing surface mass balance (SMB) and temperature values generated by an energy balance model embedded within a climate model in order to generate an ice sheet state that is amenable for use as an initial condition in fully coupled ice sheet/climate simulations
We have described and demonstrated a new procedure for generating a simulated preindustrial ice sheet state for use in fully coupled ice sheet/climate models
Summary
Ice sheets play an important role in regulating critical aspects of the climate system such as sea level rise (Foster and Rohling, 2013), atmospheric circulation (Ridley et al, 2005) and ocean circulation (Weaver et al, 2003). Ice sheet presence and evolution is a fundamental control on regional to hemispheric circulation patterns (e.g., Manabe and Broccoli, 1985), oceanic freshwater fluxes (e.g., Broecker, 1994) and regional climate behavior (e.g., Langen et al, 2012). Coupled ice sheet/climate models are potentially powerful tools for understanding the behavior of ice sheets (Hanna et al, 2013) because they are able to simulate important feedbacks between ice sheets and climate and calculate the SMB using in-line energy balance calculations. In coupled climate models, including those with integrated ice sheets, full self-consistency
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