Figure 2.4. (a) Thermodynamic feedback loops; (b) direct mechanics; and (c) indirect mechanics, all explaining the melting of the Arctic sea ice. For a color version of this figure, see www.iste.co.uk/mercier/climate.zip
(source: modified from Weiss 2008)
2.3.2. Antarctic sea ice
On the other hand, the dynamics and evolution of the sea ice surrounding the Antarctic continent are of a different nature.
Figure 2.5. Antarctic sea ice extents derived from satellite data DMSP Nimbus7 and NASA. For a color version of this figure, see www.iste.co.uk/mercier/climate.zip
(source: Parkinson 2019)
COMMENT ON FIGURE 2.5.- (a) Mean monthly sea ice extent for the southern hemisphere from January 1979 to December 2018. The February ranges are shown in red, the September ranges in green and all other ranges in black. (Box) The 40-year average annual cycle. (b) Monthly deviations determined from the monthly mean data of (a), with the same monthly color coding and with the line of least squares. (c) Mean annual sea ice extent and trend.
The spatial extension of the Antarctic sea ice is symmetrical around the continent from the South Pole and reveals a double spatial astronomical and therefore thermal logic. In addition, sea currents and winds circulate continuously around the continent in an hourly direction. They then act as a thermal barrier surrounding the continent. Unlike the Arctic Basin, the absence of a land boundary around the continent allows Antarctic sea ice to float freely towards mid-latitudes where warmer waters cause it to melt. As a result, most of the sea ice that forms during the southern winter melts during the summer season. During the winter, the Antarctic sea ice reached an average of 18 million km2 between 1981 and 2010 with a maximum extension in September. In September 2014, it even reached 20 million km2. Its minimum extension was still registered in February with less than 5 million km2 (see Figure 2.5; NSIDC 2019; Parkinson 2019).
Since record levels in 2014 and despite the significant declines in recent years in the spatial extent of the Antarctic sea ice, the trend for the period 1979-2018 still remains positive with an increase of 11,300 km2 per year (Parkinson 2019). The causes of this increase in the spatial extent of the Antarctic sea ice have not yet been agreed (Parkinson 2019). On the other hand, the impact of this variability in the extension of the sea ice around Antarctica determines the extent of pre-precipitation for the continent. Between a reduced extension and a vast extension of the sea ice, the difference in precipitation is estimated at 102 Gt per year (Wang et al. 2020).
2.4. Melting of the Earth's cryosphere
2.4.1. Melting ice sheets
2.4.1.1. The melting of Greenland
Between 2006 and 2015, the Greenland ice sheet lost ice mass at an average rate of 278 ± 11 billion tons per year (IPCC 2019). This melting represents an equivalent of 0.77 ± 0.03 mm per year in global sea level rise. Melting mainly affects the surface of the ice sheet (see Figures 2.6 and 2.7).
Figure 2.6. Total extent of melt day, or sum of daily melt area during the 1999-2019 melt season in Greenland. For a color version of this figure, see www.iste.co.uk/mercier/climate.zip
(source: NSIDC)
Since 2000, the Greenland ice sheet has experienced a general increase in melting, with a melt day area for 2019 totaling 28.3 million square kilometers. Melting has been observed over nearly 90% of the island on at least one day, even reaching the Summit station and much of the high-altitude areas. It was particularly intense along the northern edge of the ice cap, where, compared to the average from 1981 to 2010, melting occurred on an additional 35 days. The number of melt days was also slightly above average along the western flank of the ice cap, with about 15 to 20 more melt days than average. In the south and southeast, the melt was slightly below average within a few days.
This melting is caused by warm, moist air flows associated with active summer and winter cyclogenesis, from the south or southeast. These mechanisms result in increased cloud cover, low-level liquid and snowy precipitation at high elevations in the ice sheet, better absorption of long-wave radiation, and a decrease in albedo in the south and near the coast, accelerating the melting of the snowpack (Oltmanns et al. 2019).
Figure 2.7. Number of days of melt at the surface of Greenland's ice sheet between January 1 and November 17, 2019. For a color version of this figure, see www.iste.co.uk/mercier/climate.zip
(source: NSIDC, Thomas Mote, University of Georgia)
2.4.1.2. The melting of the Antarctic
Between 2006 and 2015, the Antarctic ice sheet lost ice mass at an average rate of 155 ± 19 Gt per year (0.43 ± 0.05 mm per year), mainly due to the rapid thinning and retreat of large glaciers downstream of the continent draining the West Antarctic ice sheet, especially in the Amundsen Sea and Wilkes Land in the eastern part (IPCC 2019).
The total mass loss of the Antarctic ice sheet is increasing every decade. It increased from 40 ± 9 Gt per year in 1979-1990 to 50 ± 14 Gt per year in 1989-2000, 166 ± 18 Gt per year in 1999-2009 and 252 ± 26 Gt per year in 2009-2017 (Rignot et al. 2019; see Figure 2.8).
Figure 2.8. Mass balance of the Antarctic ice sheet. For a color version of this figure, see www.iste.co.uk/mercier/climate.zip
COMMENT ON FIGURE 2.8.- The size of the circle is proportional to the absolute magnitude of the anomaly in D (dD = SMB1979-2008 - D) or SMB (dSMB = SMB - SMB1979-2008). The color of the circle indicates a loss in dD (dark red) or dSMB (light red) relative to a gain in dD (dark blue) or dSMB (light blue) in billions of tons (1,012 kg) per year. The dark color refers to dD; the light color refers to dSMB. The graphs show totals for Antarctica, Antarctic Peninsula, West Antarctica and East Antarctica. The bottom is the total mass balance distributed over the catchments with a color code ranging from red (loss) to blue (gain) (source: Rignot et al. 2019).
Between 2009 and 2017, mass loss was dominated by the Amundsen and Bellingshausen Sea sectors in West Antarctica (159 ± 8 Gt per year), Wilkes Land in East Antarctica (51 ± 13 Gt per year), and the Western and Northeastern Peninsula (42 ± 5 Gt per year). The contribution to sea level rise from Antarctica averaged 3.6 ± 0.5 mm per decade with a cumulative 14.0 ± 2.0 mm since 1979, of which 6.9 ± 0.6 mm from West Antarctica, 4.4 ± 0.9 mm from East Antarctica and 2.5 ± 0.4 mm from the Peninsula (i.e. East Antarctica is a major contributor to mass loss). Throughout the period, the mass loss was concentrated in the closest to deep circumpolar water (DCW) that is warm, salty, subterranean, which is consistent with the enhanced polar winds pushing DCW towards Antarctica to melt its floating ice shelves, destabilize glaciers and raise sea level (Rignot et al. 2019).
2.4.2. The melting of mountain glaciers