Climate Science News
Ice extent in the Arctic was below average during November. There was substantially less ice than average in the northern Barents Sea, likely due to an influx of warm ocean waters and the persistence of a strong positive Arctic Oscillation (AO). In contrast, sea ice extent in Antarctica remained unusually high.Overview of conditions
Arctic sea ice continued to expand during November, gaining 2.24 million square kilometers (865,000 million square miles) of ice since the beginning of the month. Sea ice extent for November averaged 10.24 million square kilometers (3.95 million square miles). This is 750,000 square kilometers (290,000 square miles) below the 1981 to 2010 average extent and is the 6th lowest November extent in the 35-year satellite data record. As was the case for October 2013, sea ice extent for November 2013 remained within two standard deviations of the long-term 1981 to 2010 average.Conditions in context
For the month as a whole, ice grew at near average rates throughout November at 74,800 square kilometers (28,900 square miles) per day compared to the 1981 to 2010 average of 70,500 square kilometers (27,200 square miles) per day. This was despite a period of slow ice growth during the first part of the month. At the end of the month, extent was 580,000 square kilometers (224,000 square miles) lower than average and 420,000 million square kilometers (162,000 square miles) above the same time last year.
The below average ice extent in the Arctic was largely due to a lack of ice in the Barents Sea, which has shown a pattern of low autumn and winter ice extent over the recent years. This November, the overall extent in the Barents Sea was the second lowest in the satellite record, with the lowest occurring in 2012.
The low ice in the Barents Sea is due to several possible factors. First, it could reflect the influx of warm ocean currents that inhibited ice growth. The atmosphere also played some role. Sea level pressure over the Arctic Ocean was lower than normal by as much as 9 to 12 hPa. This is consistent with the persistent strongly positive phase of the AO seen through the month; a positive AO generally leads to higher than average air temperatures over Eurasia and adjacent sea ice areas. November air temperatures in the Barents Sea were on the order of 2 to 4 degrees Celsius (4 to 7 degrees Fahrenheit) above average. The higher than average temperatures may also simply reflect the lack of sea ice in the Barents Sea. This is because under open water conditions, the ocean readily releases heat to the overlying atmosphere.November 2013 compared to previous years.
Including 2013, the linear trend in November ice extent is –4.9% per decade relative to the 1981 to 2010 mean, or –53,500 square kilometers per year (–20,700 square miles per year).Extensive ice in Antarctica
While it is early winter in the Arctic, it is early summer in the Antarctic. Continuing patterns seen in recent years, Antarctic sea ice extent remains unusually high, near or above previous daily maximum values for each day in November. Sea ice is anomalously extensive across the Peninsula, the Amundsen Sea, and the Wilkes Land sectors. However, it has retreated in the northern Ross Sea region—where it had been far to the north of the mean ice edge—to more typical extent locations. Sea ice extent averaged 17.16 million square kilometers (6.63 million square miles) for November. The long-term 1981 to 2010 average extent for this month is 16.30 million square kilometers (6.29 million square miles).
Beginning in October, wind conditions in the Ross Sea shifted from a direction favoring a northward growth of sea ice to a more westerly direction. This and the coming of sunshine and warmth with spring led to a retreat from record ice extents there. However, November brought cool conditions (1 to 3 degrees Celsius, or 2 to 5 degrees Fahrenheit, below the 1981 to 2010 average) around the Peninsula and much of the western hemisphere of the Southern Ocean. Winds have also favored a northward drift along the western Peninsula. Overall, cool conditions and extensive ice around the Peninsula strongly contrast with the past few decades’ shift to a more ice free Peninsula and extensive surface melting there. Palmer Station, the U.S. Antarctic research base, was once again briefly surrounded by sea ice this winter, as it was in 2012.
Overall, the extreme sea ice extent may be linked to strong variations in the westerly wind flow, the main circulation around Antarctica. Strong westerly flow favors ice growth in autumn and early winter, and this was the case; however, as sea ice approached a maximum, the westerly wind pattern abated, allowing ice to drift even further north than usual, in some places urged on by southerly winds.
At the same time, part of the interior has seen record warm winter events, with several daily temperature records set at the South Pole . These warm events are also linked to the reduction in westerly wind strength in August to October. Weaker westerly winds allow more north-south flow into Antarctica, occasionally bringing relatively warm air masses into the interior. Between September 11 and September 15, usually a time of unimaginable cold, four daily maximum temperature records were set, in one case by more than 8.5 degrees Celsius (15.3 degrees Fahrenheit). On September 13, the temperature reached –27.7 degrees Celsius (–17.9 degrees Fahrenheit), a temperature more typical of early summer conditions.Big berg backs out of bay
In Pine Island Bay, a medium-sized iceberg that had been pinned on a shoal near the front of Pine Island Glacier began to drift into the Southern Ocean. The iceberg has received significant attention because it has broken away from Antarctica’s largest glacier (as measured by amount of ice moved per year). Pine Island Glacier has accelerated significantly in recent years as increasingly warm ocean water at depth have melted and thinned the ice at the point where the glacier goes afloat. NASA scientists and other groups like the British Antarctic Survey have installed instruments and are making further measurements to determine if the glacier will accelerate further in the aftermath of the loss of the iceberg.Increased methane emission from the Siberian sea floor
A recent paper by colleagues at the University of Alaska Fairbanks suggests that ocean bottom water temperatures are increasing as Arctic sea ice cover has decreased, leading to a recent increase in methane flux from the seabed to the atmosphere. Ship-based observations show that methane concentrations in the air above the East Siberian Sea Shelf are nearly twice as high as the global average.
The Siberian continental shelf is a vast region of shallow-water covered continental crust, comprising about 20% of the global area of the continental shelf. During the last glacial maximum, much of the shelf was exposed to the cold atmosphere and froze to a depth of about 1.5 kilometers (about 1 mile). Layers of sediment below the permafrost slowly emit methane gas, and this gas has been trapped for millennia beneath the permafrost. As sea levels rose at the end of the ice age, the shelf was once again covered by relatively warm ocean water, thawing the permafrost and releasing the trapped methane. Methane is a potent greenhouse gas but is relatively short-lived in the atmosphere (about 12 years), leading to reduced global warming potential over time. In the short-term however, methane has a global warming potential 86 times that of carbon dioxide.Reference
Shakhova, N., I. Semiletov, I. Leifer, V. Sergienko, A. Salyuk, D. Kosmach, D. Chernykh, C. Stubbs, D. Nicolsky, V. Tumskoy, and Ö. Gustafsson. 2013. Ebullition and storm-induced methane release from the East Siberian Arctic Shelf. Nature Geoscience, http://dx.doi.org/10.1038/ngeo2007 .
Nearly frozen up by the end of October, the Arctic Ocean still showed small regions of open water within the Beaufort and Chukchi seas on its western side, and within the Kara Sea on its eastern side. These open water areas contributed to warmer than average air temperatures over the western Arctic.Overview of conditions
Arctic sea ice continued to expand during October as temperatures dropped and the number of daylight hours diminished, gaining 3.21 million square kilometers (1.24 million square miles) of ice since the beginning of the month. Average ice extent for October was 8.10 million square kilometers (3.13 million square miles), making it the 6th lowest October extent in the 35-year satellite data record. This was 810,000 square kilometers (313,000 square miles) below the 1981 to 2010 average extent. The October 2013 extent remains within two standard deviations of the long-term 1981 to 2010 average.
As open water areas refreeze and continue to lose the heat gained during the summer back to the atmosphere, near surface air temperatures have remained higher than average over areas that have not yet completely frozen over. As of the beginning of November, small parts of the Beaufort, Chukchi, and Kara seas remain ice free, while the East Siberian and Laptev seas have completely frozen over. Higher than average air temperatures have been observed over the ice-free regions while the rest of the Arctic is at near average to below average temperatures. This is in contrast to the first half of October 2012 when large parts of the East Siberian and Laptev seas remained ice free and the entire Arctic was warmer than average.Conditions in context
Ice grew at rates faster than average throughout October, at 103,500 square kilometers (40,000 square miles) per day compared to the 1981 to 2010 average of 87,500 square kilometers per day (33,800 square miles per day). However, this rate is slower than last year, when ice extent doubled during the month of October. Nevertheless, the ice cover is more extensive than in 2012. At the end of the month the extent was 710,000 square kilometers (274,100 square miles) below average and 1.1 million square kilometers (424,700 square miles) above the same time last year.
While the sea ice extent this summer was higher than the past several summers, extent remained anomalously low compared to the long-term mean, and the larger regions of open water during summer were able to absorb the sun’s energy, leading to higher sea surface temperatures. Before the ocean can refreeze in the autumn, it releases this excess heat back to the atmosphere, resulting in higher than average air temperatures. In October, air temperatures along the coastal Beaufort Sea were 6 to 8 degrees Celsius (11 to 14 degrees Fahrenheit) higher than average. Air temperatures were also 2 to 4 degrees Celsius (4 to 7 degrees Fahrenheit) higher than average over much of the western and central Arctic and near Greenland and the Canadian Archipelago.October 2013 compared to previous years
The year 2013 marks the first October with an extent above 8 million square kilometers (3.09 million square miles) since 2009 and only the second since 2006. From 1979 to 2006, average October extent was never below 8 million square kilometers, and several years had October extents above 9 million square kilometers (3.47 million square miles). The lowest October extent, less than 7 million square kilometers (2.7 million square miles), was observed in 2007. The linear trend in October ice extent is –7.1 % per decade relative to the 1981 to 2010 mean, or –63,400 square kilometers per year (–24,500 square miles per year).Sea ice decline and the greening of Arctic tundra
As sea ice extent declined over the past years, Arctic tundra has received an increased amount of summer warmth and has gotten greener. Arctic tundra (Figure 4) is a maritime biome, most of which can be found within 100 kilometers (62 miles) of seasonally ice-covered seas. This proximity to sea ice limits the tundra’s exposure to available warmth and vegetation growth. Over 30 years of remote sensing data show that the decline in sea ice extent corresponds to land surface warming (Figure 5, left panel) and increased vegetation cover (Figure 5, right panel, Maximum Normalized Difference Vegetation Index, or MaxNDVI). When sea ice extent is below average in coastal seas, land surfaces warm, and satellites see a stronger signal of vegetation.
However, the same data offer a few puzzles. While land surface warming and vegetation cover have steadily increased in the vicinity of Greenland over the last thirty years, warming and vegetation have actually decreased in some parts of Eurasia over the last decade. This suggests that once sea ice declines or the climate warms beyond a limit, other processes begin to play a more central role in summer climate variability, such as moisture availability in the soil or cloudiness, which can lead to cooler conditions during the northern summer. Another mystery is the decline in vegetation cover over the southwest Alaskan tundra despite an increase in land surface temperature over the same period. Researchers are looking into these puzzles as they think ahead to what the tundra may look like in a future of ice-free summers.Further reading
Bhatt, U.S., D.A. Walker, M.K. Raynolds, P.A. Bieniek, H.E. Epstein, J.C. Comiso, J.E. Pinzon, C.J. Tucker, and I.V. Polyakov. 2013. Recent Declines in Warming and Arctic Vegetation Greening Trends over Pan-Arctic Tundra. Remote Sensing (Special NDVI3g Issue), 5, 4229-4254; doi:10.3390/rs5094229.
Bhatt, U.S., D.A. Walker, M.K. Raynolds, J.C. Comiso, H.E. Epstein, G. Jia, R. Gens, J.E. Pinzon, C.J. Tucker, C.E. Tweedie, and P.J. Webber. 2010. Circumpolar Arctic tundra vegetation change is linked to sea-ice decline. Earth Interactions. August 2010, Vol. 14, No. 8: 1-20. doi: 10.1175/2010EI315.1.
Raynolds, M.K., Walker, D.A. & Maier, H.A. 2006. NDVI patterns and phytomass distribution in the circumpolar Arctic. Remote Sens. Environ. 102: 271-281.
Walker, D.A. et al. 2005. The Circumpolar Arctic Vegetation Map. J. Veg. Sci., 16, 267–282.
Path of typhoon Wipha with its intensity overlaid on the two passes of Saral and Jason-2: Saral overflew the typhoon on Oct 15 when the typhoon was in category 1 and jason-2 on Oct 14 when the typhoon was in category 3 (Credits CNES/CLS)The Significant Wave Height measurements observed by Saral are displayed below. The peak value of 60.95 feet or 18.58 meters is impressive as well as the width of the seas in excess of 45 feet or 13.7m (a length of 370 km). Saral data have been fully integrated into warning and forecast operations at NOAA Ocean Prediction Center.
Significant wave height seen by Saral on October 15 at 20:21 UTC. The wave heights are in feet and are color coded by the color scale in the upper right. The time stamp is in red and plotted every minute. (Credits Joe Sienkiewicz, NOAA Ocean Prediction Center).Wind Speed values measured by Saral altimeter reached values up to 28 m/s.
Wind Speed values seen by Saral and Jason-2 over Typhoon Wipha in m/s. (Credits CNES/CLS)Further information:
- Applications: Hurricanes
- Unisys weather Service: http://weather.unisys.com/hurricane
- Nasa earth observatory: http://earthobservatory.nasa.gov/NaturalHazards
- Carrère et al., 2009: "Observing and Studying Etreme Low Pressure Events with Altimetry"
- Quilfen, Y.; Tournadre, J.; Chapron, B. Altimeter dual-frequency observations of surface winds, waves and rain rate in tropical cyclone Isabel. J. Geophys. Res. 2006, 111, C01004.
This summer, Arctic sea ice loss was held in check by relatively cool and stormy conditions. As a result, 2013 saw substantially more ice at summer’s end, compared to last year’s record low extent. The Greenland Ice Sheet also showed less extensive surface melt than in 2012. Meanwhile, in the Antarctic, sea ice reached the highest extent recorded in the satellite record.Overview of conditions
Arctic sea ice extent reached its annual minimum on September 13. After the minimum, extent remained largely unchanged for much of the middle of September, but increased rapidly toward the end of the month with the onset of strong autumn cooling.
Arctic sea ice extent averaged for September 2013 was 5.35 million square kilometers (2.07 million square miles). This was 1.17 million square kilometers (452,000 square miles) below the 1981 to 2010 average extent. September 2013 ice extent was 1.72 million square kilometers (664,000 square miles) higher than the previous record low for the month that occurred in 2012.Conditions in context
The rate of ice loss varied through the summer. Both May 2012 and May 2013 saw near average extents and rates of decline. This year, the rate of ice loss sped up in late June and early July, then settled into a near-average rate of decline, with extent approximately 500,000 square kilometers (193,000 square miles) greater than the same time in 2012. Ice loss then slowed down in August to only a little faster than average rates of loss for that time of year. In comparison, during 2012, the rate of loss accelerated in early June and through July, then accelerated even more in August to produce a new record low extent in September 2012.
Overall, 10.03 million square kilometers (3.87 million square miles) of ice were lost between the 2013 maximum and minimum extents. This was the seventh summer that more than 10 million square kilometers of ice extent were lost; all but one of the seven (the summer of 1990) have occurred since 2007.September 2013 compared to previous years
September average sea ice extent for 2013 was the sixth lowest in the satellite record. The 2012 September extent was 32% lower than this year’s extent, while the 1981 to 2010 average was 22% higher than this year’s extent. Through 2013, the September linear rate of decline is 13.7% per decade relative to the 1981 to 2010 average.What a difference a year makes
Contrasting weather conditions were a significant factor in this year’s higher sea ice extent and lower Greenland Ice Sheet melt intensity, compared to last year. This summer saw air temperatures at the 925 hPa level that were 1 to 3 degrees Celsius (2 to 5 degrees Fahrenheit) lower than last summer. It was also a cool summer compared to recent years over much of the Arctic Ocean, and even cooler than the 1981 to 2010 average in some regions, particularly north of Greenland.
While 2012 and 2013 extents were similar through May, weather patterns from June to August helped retain more ice. Last summer was marked by lower than average pressure over the Eurasian side of the Arctic and higher than average pressure over Greenland. This resulted in a dipole-like wind pattern that favored ice transport across the ocean and the import of heat from southern latitudes along the Eurasian side of the Arctic. In contrast, this summer was characterized by unusually low pressure over much of the Arctic Ocean, which limited heat import from the south and brought more extensive cloud cover, keeping temperatures lower. In addition, the winds associated with the low pressure caused the ice cover to spread out and cover a larger area.
Over land, the cool spring resulted in greater than average March and April snow cover for the Northern Hemisphere. However, as in recent years, the snow melted rapidly, and by May, snow cover was at near record lows. Cooler weather conditions also limited surface melt on the Greenland Ice Sheet, which was still greater than the 1981 to 2010 average, but not near the record set in 2012 (see our Greenland Ice Sheet Today post for more details).Ice thickness and age
The pattern of ice thickness for the summer of 2013 is similar to what has been seen in recent years. According to data from the European Space Agency CryoSat-2 radar altimeter, the spring melt season started with an Arctic ice cover thinner than in any recent year. This corroborates thickness information inferred from a calculation of ice age that showed first-year ice, which is thinner and more vulnerable to melt, over a significant part of the Arctic Ocean as the melt season started (see our earlier post). Older, thicker ice remained in a region roughly between the North Pole and the Canadian Archipelago and the Greenland coast.
In recent summers, there has been considerable transport of older ice into the Beaufort and Chukchi seas, where it has been broken up and exposed to a warm ocean and high air temperatures. This has been a major factor in the loss of multiyear ice over the last decade. This year was notably different. Because this year’s wind pattern was different than 2012, the multiyear ice largely remained in a compact area along the Canadian Archipelago and did not circulate into the Beaufort and Chukchi seas. The cooler conditions this summer also helped preserve more of the first-year ice through the summer.
The first-year ice that survived the summer, now defined as second-year ice, will thicken through autumn and winter. However, it would take several more cool years in a row to build the ice cover back to the state it was in during the 1980s, which consisted of a larger proportion of thicker, multiyear ice that was more resistant to melt. While ice in the Arctic will thicken through this autumn and winter, winds may also transport some of the thicker ice out of the Arctic Ocean and into the North Atlantic.Another record high in the Antarctic
Antarctic sea ice extent reached 19.47 million square kilometers (7.52 million square miles) on September 22, a record high maximum extent relative to the satellite record, and slightly above the previous record high set last year. This year’s maximum extent was 3.6% higher than the 1981 to 2010 average Antarctic maximum, representing an ice edge that is 35 kilometers (approximately 22 miles) further north on average. Overall, Antarctic September sea ice extent is increasing at 1.1% per decade relative to the 1981 to 2010 average. This increase is likely due to a combination of factors, including winds and ocean circulation. A recent paper by our colleague Jinlun Zhang at the University of Washington concludes that changes in winds are resulting in both more compaction within the ice pack and more ridging, causing a thickening of the pack and making it more resistant to summer melt.Table 1: Previous Arctic sea ice extents for the month of September *
* Note that the dates and extents of the minimums have been re-calculated from what we posted in previous years; see our Frequently Asked Questions for more information.Reference
Zhang, J. In press. Modeling the impact of wind intensification on Antarctic sea ice volume. J. Climate, doi:10.1175/JCLI-D-12-00139.1.
On September 13, Arctic sea ice reached its likely minimum extent for 2013. The minimum ice extent was the sixth lowest* in the satellite record, and reinforces the long-term downward trend in Arctic ice extent. Sea ice extent will now begin its seasonal increase through autumn and winter. Meanwhile, in the Antarctic, sea ice extent reached a record high on September 18, tied with last year’s maximum.
Please note that this is a preliminary announcement. Changing winds could still push ice floes together, reducing ice extent further. NSIDC scientists will release a full analysis of the melt season in early October, once monthly data are available for September.Overview of conditions
On September 13, 2013, sea ice extent dropped to 5.10 million square kilometers (1.97 million square miles). This appears to have been the lowest extent of the year. In response to the setting sun and falling temperatures, ice extent will now climb through autumn and winter. However, a shift in wind patterns or a period of late season melt could still push the ice extent lower. The minimum extent was reached two days earlier than the 1981 to 2010 average minimum date of September 15.Conditions in context
This year’s minimum was 1.69 million square kilometers (653,000 square miles) above the record minimum extent in the satellite era, which occurred on September 16, 2012, and 1.12 million square kilometers (432,000 square miles) below the 1981 to 2010 average minimum.Varying distribution of ice in 2013 versus 2012
Comparing this year’s minimum extent to 2012, while extent was higher on average this year, there were variations from region to region. There was considerably higher sea ice extent in the Beaufort, Chukchi, and East Siberian sea regions, with the ice edge several hundred kilometers farther south compared to last year. This year the Canadian Archipelago also retained much more ice, keeping the Northwest Passage closed. The most notable area of less ice this year compared to last was off the east coast of Greenland, south of Fram Strait. Other small areas of decreased extent were found north of the Kara and Laptev seas.
See an animation of this summer’s sea ice extent produced by the NASA Scientific Visualization Studio at http://svs.gsfc.nasa.gov/goto?4104.Previous minimum Arctic sea ice extents** Table 1. Previous minimum Arctic sea ice extents YEAR MINIMUM ICE EXTENT DATE IN MILLIONS OF SQUARE KILOMETERS IN MILLIONS OF SQUARE MILES 2007 4.17 1.61 September 18 2008 4.59 1.77 September 20 2009 5.13 1.98 September 13 2010 4.63 1.79 September 21 2011 4.33 1.67 September 11 2012 3.41 1.32 September 16 2013 5.10 1.97 September 13 1979 to 2000 average 6.70 2.59 September 13 1981 to 2010 average 6.22 2.40 September 15
* According to near-real-time data, this year’s minimum extent is slightly lower than 2009. However, the ranking between 2009 and 2013 is close, and may change once the final version of the data are processed. See our Frequently Asked Questions: Do your data undergo quality control? for more information about near-real-time data.
** Note that the dates and extents of the minimums have been re-calculated from what we posted in previous years; see our Frequently Asked Questions for more information.
Following a relatively cool summer, sea ice extent fell to a little over 5 million square kilometers (1.93 million square miles) over the first two weeks of September and is at or near the minimum extent for the year. NSIDC will announce the final minimum extent and date once it is confirmed.Overview of conditions
Arctic sea ice extent as of September 16, 2013 was 5.10 million square kilometers (2.00 million square miles). This is substantially more ice than observed on the same date last year, yet sea ice extent remains quite low compared to the long-term 1981 to 2010 average. As is typical for this time of year, winds or currents can compact or spread apart the ice, resulting in small daily fluctuations of the ice cover.
During the first two weeks of September, sea ice extent continued to decline in the East Siberian, Laptev, and Kara seas while staying essentially constant in the Beaufort and Chukchi seas since the beginning of September. The Northwest Passage has seen more extensive ice this summer since 2007 and is not open. On the Eurasian side of the Arctic, the Northern Sea Route appears to have opened up briefly in September.Conditions in context
Ice loss through the first two weeks of September was faster than average. Air temperatures at the 925 hPa level were 1 to 3 degrees Celsius (2 to 5 degrees Fahrenheit) higher than average over much of the Arctic Ocean the first part of the month, in stark contrast to most of the summer when cooler temperatures dominated. Below average temperatures were found in the Beaufort and Chukchi seas where ice growth began around the first week of the month.
Even though extent at the beginning of this summer was similar to last year, the melt season ended with considerably more ice. This is not surprising, as climate models consistently project that there will be large variations in summer ice extent from year to year. A cool summer can help to retain a thin layer of ice, increasing the overall ice extent. Conversely, a warm summer can help to remove much of the thin ice cover.Cold summer over central Arctic and Greenland
As a whole, air temperatures this summer have been below average over most of the central Arctic Ocean and Greenland, helping to slow down ice melting. Compared to the 1981 to 2010 average, air temperatures at the 925 hPa level have been -0.5 to -2.0 degrees Celsius (-0.9 to -3.6 degrees Fahrenheit) below average over central Greenland, north of Greenland and towards the pole, and over the Canadian Archipelago. Unusually low temperatures are also noted over the East Siberian Sea, where ice cover has remained near average throughout the summer.
The cool conditions that have prevailed this summer are even more remarkable when compared to the last six years, which have seen very low September sea ice extents. Compared to the 2007 to 2012 average, air temperatures at the 925 hPa level averaged over June, July and August were lower this summer throughout most of the Arctic by -0.5 to -3.5 degrees Celsius (-0.9 to -6.3 degrees Fahrenheit). The previous six summers have been dominated by high sea level pressure over the Beaufort Sea and Greenland, paired with low sea level pressure over Eurasia—a pattern that helps to transport warm air into the Arctic. In contrast, this summer was characterized by low sea level pressure over the central Arctic and Greenland. Cooler conditions have also led to less surface melting on the Greenland Ice Sheet.Sea surface temperature trends
Colleagues Michael Steele and Wendy Ermold at the University of Washington found that sea surface temperatures (SSTs) in the Arctic Ocean were above the 1982 to 2006 average during August, as has been the case since 2007. Sea ice retreat was later and not as extreme relative to recent years in the western Arctic (i.e., the Beaufort, Chukchi, and East Siberian seas) and as a result, SSTs were near the long-term average there. SSTs were well above average in the eastern Arctic (Laptev, Kara, and Barents seas). This can be linked to early ice retreat in the Laptev Sea. However, warm conditions in the southern Barents and Kara seas are likely influenced by advection of warm water from the south in the Norwegian Sea. Overall, for the period 2007 to 2013 there is a pattern of declining SSTs in the western Arctic, and increasing SSTs in the eastern Arctic.Antarctic sea ice extent
As ice extent approaches its summer minimum in the Arctic, the winter maximum is near for Antarctica. This year, as was the case in 2012, Antarctic sea ice extent is very high. As of September 16, the current extent is 19.45 million square kilometers (7.51 million square miles), a record for this date with respect to the 1979 to 2012 satellite era. This is about 3.9% above the average maximum extent for the 30-year comparison period 1981 to 2010. In contrast, this year’s Arctic summer minimum ice extent is approximately 30% below levels seen in the early 1980s, and the 2012 record low extent was around 60% below levels seen in the same period. This helps to highlight why scientists are more concerned by Arctic ice shrinkage than by Antarctic ice expansion.
Antarctic weather patterns in August were unusual. Contrary to a 50-year trend towards stronger westerly wind flow—a pattern associated with both ozone loss and increased heat-trapping gases in the atmosphere—August 2013 saw a period of very low westerly wind speed across the continent.
* Note: On September 19, 2013, we revised a sentence in this section for clarity. A sentence that originally read, “In contrast, this year’s Arctic summer minimum ice extent is approximately 30% below the 30-year period average, and the 2012 record low extent was nearly 60% below the average.” now reads, “In contrast, this year’s Arctic summer minimum ice extent is approximately 30% below levels seen in the early 1980s, and the 2012 record low extent was around 60% below levels seen in the same period.”
- OGDR and IGDR products have been distributed to all Users from June 25th; GDR products are available to PIs since August 2nd.
- Some algorithms are still to be tuned: neural network used for radiometer data ground processing, Sea State Bias computation, altimeter wind speed and ICE2 retracking.
- According to users presentations, the main message of this meeting is the easiness to use the data (thanks to the ground segment operationnality and the expertise of the users). The level of quality achieved by the products in terms of accuracy, data latency and availability is such that the Saral/AltiKa data are now operationnaly integrated in several forecast systems (in Europe : CNES SALP, Météo France, Mercator, ECMWF, in India : ISRO/INCOIS, in Australia : CSIRO, in USA : NOAA, Navy).
- The catchword for the Saral/AltiKa data could be "ready to use".
Sea ice continued its late-season summer decline through August at a near-average pace. Ice extent is still well above last year’s level, but below the 1981 to 2010 average. Open water was observed in the ice cover close to the North Pole, while in the Antarctic, sea ice has been at a record high the past few days.Overview of conditions
Sea ice extent for August 2013 averaged 6.09 million square kilometers (2.35 million square miles). This was 1.13 million square kilometers (398,000 square miles) below the 1981 to 2010 average for August, but well above the level recorded last year, which was the lowest September extent in the satellite record. Ice extent this August was similar to the years 2008 to 2010. These contrasts in ice extent from one year to the next highlight the year-to-year variability attending the overall, long-term decline in sea ice extent.
Extent in the Beaufort and Chukchi seas has dropped below average, after near average conditions in July. The only region with average extent is the East Siberian Sea.Conditions in context
Relatively cool conditions over the central Arctic Ocean continued, a pattern that has characterized this summer. Temperatures at the 925 hPa level in the high Arctic (north of Greenland to the North Pole) were 0.5 to 3 degrees Celsius (1 to 5 degrees Fahrenheit) below the 1981 to 2010 average. In comparison, temperatures in coastal areas of the Arctic were mostly near average, and temperatures in the Barents and Beaufort seas were about 2 degrees Celsius (4 degrees Fahrenheit) above average. The distribution of the temperature anomalies can be related to the sea level pressure pattern. Below-average sea level pressures were linked to cloudy and cool conditions near the North Pole and extending into the northern North Atlantic. In contrast, above-average pressures dominated the Eurasian coast.August 2013 compared to previous years
The seasonal decline of extent through the month of August was slightly above average at 56,400 square kilometers (21,800 square miles) per day, but more than a third slower than the record decline rate in August 2012. This year’s August extent was the sixth lowest in the 1979 to 2013 satellite record.
August 2013 ice extent was 1.38 million square kilometers (533,000 square miles) above the record low August extent in 2012. The monthly trend is –10.6% per decade relative to the 1981 to 2010 average.Water near the pole
Earlier this summer, there was considerable interest in seeing liquid water in the North Pole Environmental Observatory (NPEO) web cam. As explained in our August 7 post, that region was simply a shallow melt pond of water atop the ice and not an actual opening in the ice. Nevertheless, our August 19 post described an extensive region of low ice concentration located fairly close to the pole.
Now, a large hole (roughly 150 square kilometers or 58 square miles) of near-zero ice concentration appears to have opened up at about 87 degrees North latitude. Small areas of open water are common within the ice pack, even at the North Pole, as the ice pack shifts in response to winds and currents, resulting in cracks (called leads) in the ice. The current opening seen in our satellite imagery is much larger. In 2006, a larger polynya appeared in the Beaufort and Chukchi seas, but it was much farther south.Melting ice from above and below
It may seem contradictory for a polynya-like opening to form near the pole while temperatures are lower than average, but it highlights the complex interplay between the ice, atmosphere, and ocean. Such openings in the ice occur two ways: through winds pushing the ice apart, or through melting. Both processes likely played a role in forming the current opening, but another key factor is a significant amount of thin, first-year ice in the region. This thin ice was more likely to melt completely than surrounding thicker ice. Heat from the ocean also contributes to melting of the ice from below, even though air temperatures have been below average in the region. Buoys that measure ice mass can provide information on surface and bottom melting.
During the summer of 2013 there were six ice mass balance buoys deployed in the Arctic over a wide area (red dots in Figure 5). The buoys were deployed in undeformed, multiyear ice, with a thickness between 2.2 and 3.5 meters (7 and 11 feet) before melt began. Data from the buoys show that the amount of surface ice melting ranged from 0 in the central Arctic, to 75 centimeters (30 inches) in the Beaufort Sea. Bottom melting varied from 8 to 108 centimeters (3 to 43 inches). The largest amount of bottom melting was observed at a buoy near the ice edge in the Beaufort Sea. This buoy had the largest total amount of melt, thinning from 339 centimeters (133 inches) in early June, to 157 centimeters (62 inches) on August 28. Ice thicknesses at the other buoys on August 28 ranged from 121 to 267 centimeters (48 to 105 inches). While bottom melting is continuing in some locations, most of this year’s surface melting has occurred. Data from the ice mass balance buoys are available at http://imb.crrel.usace.army.mil. (Thanks to Jackie Richter-Menge and Don Perovich at the Cold Regions Research and Engineering Laboratory [CRREL] for this part of the discussion.)
Arctic sea ice extent maintained a steady, near-average pace of retreat through the first half of August, making it highly unlikely that a new record low minimum will be reached this year. Nevertheless, there are extensive areas of low concentration ice, even in regions close to the North Pole, atmospheric pressure and temperature patterns this summer have differed markedly from those experienced in 2012; cooler than average conditions have prevailed over much of the Arctic Ocean. By contrast, Antarctic sea ice is near a record maximum extent for mid-August.Overview of conditions
Sea ice retreat through the first half of August was near average, bringing the ice extent to 5.94 million square kilometers (2.30 million square miles). Sea ice extent continues to track well below average levels (average of 1981 to 2010), though remains within two standard deviations of the long-term mean. Retreat rates increased slightly in the western Beaufort Sea and Chukchi Sea, but ice cover remains extensive in those regions compared to 2012. Another major difference between ice extent during 2012 and this year is the much greater extent in the East Siberian Sea. Low ice extent in this region observed last year was in part attributed to the effects of the “Great Cyclone of 2012” (see previous post of August 14, 2012). On the eastern side of the Arctic near Europe and Greenland, the extent remains below average.Conditions in context
The sea ice retreat rate averaged from August 1 to 18 was near average at approximately 75,000 square kilometers (29,000 square miles) per day. However, satellite data show extensive low-concentration areas within the ice cover, which appear to have developed in response to the frequent passage of storm systems. These weather patterns also result in lower-than-average air temperatures over the Arctic. Temperatures in the central Arctic at the 925 hPa level have been 2 to 4 degrees Celsius (4 to 7 degrees Fahrenheit) below average since late July.A bit thin on top
Satellite data from the AMSR-2 instrument and MODIS show an unusually large expanse of low-concentration sea ice (20 to 80% cover) within our extent outline (15% or greater, using the SSM/I sensor) spanning much of the Russian side of the Arctic and extending to within a few degrees of the North Pole. A small area north of the Kara Sea has concentrations below 30%. This is likely in part a result of the dispersive effect of low-pressure systems that have migrated across the central Arctic over the past month. While some of the low concentrations recorded by AMSR-2 may be due to surface melt on sea ice, the MODIS image confirms that a large region is covered by isolated floes. The tendency towards a more open pack, with large areas of open water between ice floes, has increased in the past decade as the ice cover has thinned, as well as a tendency for formation of large polynyas (see ASINA posts for September 2006) and areas of pack detached from the main Arctic ice cover (such as mid-August 2012). The University of Washington’s Pan-Arctic Ice Ocean Modeling and Assimilation System (PIOMAS) model and other models of ice thickness continue to indicate thin ice cover this summer.Not like last year
A comparison of average temperature and sea level pressure maps for June and July of 2012 (left diagrams) and 2013 (right diagrams) help us to understand why ice extent is higher in 2013. The pattern of unusually low pressure centered near the pole in 2013 has helped to spread the ice out and is consistent with generally cool conditions over much of the Arctic Ocean, inhibiting melt. By contrast, in the summer of 2012, a broad region of unusually high pressure centered over Greenland, in combination with below average pressure centered over the East Siberian and Chukchi seas, led to winds over the Beaufort Sea with a more southerly component than is usually the case, leading to warm conditions. That high pressure last year over Greenland also contributed to a record melt season for the Greenland ice sheet. Melt this year over the ice sheet has been more moderate, though still above rates seen in the 1990s. See our upcoming Greenland Today site post later this week.Can’t get there from here
Projections of the likely minimum extent this year based on retreat rates from past years argue that it is highly unlikely that sea ice will surpass the record-setting low extent seen in 2012. With retreat rates similar to those of 2007 to 2012, the minimum extent would be near 5.0 million square kilometers (2.0 million square miles) in mid-September.Record extent in the Antarctic
Antarctic sea ice extent for August 19 is 18.70 million square kilometers (7.22 million square miles), a record or near-record high level (August 19, 2010 was similarly high), led by unusually extensive ice in the Bellingshausen, Amundsen, and Ross seas, and in the western Indian Ocean sector. Climate conditions since June have been variable, but the most recent surge in ice growth has occurred during a period of unusually high pressure over the center of the continent, resulting in a slowing of the circumpolar winds, warm winter conditions for the central ice sheet areas (Vostok Station and Amundsen-Scott South Pole Station both had periods of spring-like -30s earlier in the month), and cold conditions in the Bellingshausen, allowing ice to grow extensively there.