Abstract
Abstract. In the present work, we simulate the Pliocene climate with the EC-Earth climate model as an equilibrium state for the current warming climate induced by rising CO2 in the atmosphere. The simulated Pliocene climate shows a strong Arctic amplification featuring pronounced warming sea surface temperature (SST) over the North Atlantic, in particular over the Greenland Sea and Baffin Bay, which is comparable to geological SST reconstructions from the Pliocene Research, Interpretation and Synoptic Mapping group (PRISM; Dowsett et al., 2016). To understand the underlying physical processes, the air–sea heat flux variation in response to Arctic sea ice change is quantitatively assessed by a climate feedback and response analysis method (CFRAM) and an approach similar to equilibrium feedback assessment. Given the fact that the maximum SST warming occurs in summer while the maximum surface air temperature warming happens during winter, our analyses show that a dominant ice-albedo effect is the main reason for summer SST warming, and a 1 % loss in sea ice concentration could lead to an approximate 1.8 W m−2 increase in shortwave solar radiation into open sea surface. During the winter months, the insulation effect induces enhanced turbulent heat flux out of the sea surface due to sea ice melting in previous summer months. This leads to more heat released from the ocean to the atmosphere, thus explaining why surface air temperature warming amplification is stronger in winter than in summer.
Highlights
As shown in the monitoring at Mauna Loa Observatory in Hawaii, the CO2 concentration in the atmosphere passed the 400 ppm threshold by September 2016
As sea ice concentration (SIC) and incoming solar radiation in the polar region vary with season, we examine the response of net shortwave radiation to sea ice change for every month
Arctic amplification in the Pliocene has previously been addressed from reconstructed data (e.g. Robinson et al, 2008; Brigham-Grette et al, 2013); these data only tell part of the story because of a scarcity of data sites
Summary
As shown in the monitoring at Mauna Loa Observatory in Hawaii (https://www.esrl.noaa.gov/gmd/obop/mlo/, last access: 30 January 2019), the CO2 concentration in the atmosphere passed the 400 ppm threshold by September 2016. While most of the previous studies on the contributions of the sea ice effect to Arctic amplification focus on contemporary trends or future projections, here the Pliocene simulation is selected for three reasons. (1) The Pliocene epoch (approximately 3 million years ago), the most recent warm period with CO2 concentrations similar to today, is an analogue of future climate change and an appropriate past time slice to examine regarding sea ice effects of albedo and insulation (Haywood et al, 2016a). Burt et al (2016) and Kim et al (2016) addressed the relationship between sea ice loss and air–sea interface heat budget using the Community Earth System Model (CESM) simulation and cyclo-stationary empirical orthogonal function (CSEOF) analysis, respectively.
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