Warm Northerly Winds Contributed to Antarctic Sea Ice to Reduce
The role of atmospheric forcing and climate fluctuations in identifying the causes of the sea ice retreat.
A recent study conducted by researchers from the National Centre for Polar and Ocean Research (NCPOR), Goa, has revealed the reasons behind the lowest Antarctic Sea Ice Extent (SIE) in February 2022.
They have investigated the role of atmospheric forcing and climate fluctuations in identifying the causes of the sea ice retreat. The lowest Sea Ice Extent (SIE) record was assumed to result from the sea ice recession that began in September 2021. SIE is the area of ice that covers the arctic ocean at a given time.
There is a difference between sea ice area and sea ice extent. The Sea ice area is the total region covered by ice. In contrast, sea ice extent is the whole region with at least 15 per cent sea ice cover.Sea ice plays a vital role in reflecting sunlight into space, regulating ocean and air temperature, circulating ocean water, and maintaining animal habitats. As per the data provided by NASA, the summer SIE is shrinking by 12.6% per decade due to global warming.
According to the researchers, SIE reached a record low of 2.16 × 106 km2 in February 2022, 43% lower than the mean extent of the previous February months since the satellite era. However, the second-lowest SIE was recorded from November 2021 to January 2022. The Weddell Sea, Ross Sea, and Bellingshausen/Amundsen Seas (ABS) sectors experienced the maximum sea ice change on a regional scale.
“The record-low SIE occurred when the Amundsen Sea Low (ASL) pressure centre was intensified, with the Southern Annular Mode (SAM) at its positive phase. Together, these two climate fluctuations played a role in modifying the pressure and wind patterns in Antarctica. The warm northerly winds largely contributed to decreased SIE,” The researchers inform.
The study also investigated the Polar Cap Height (PCH), which demonstrates a strengthening of the stratospheric polar vortex and positive polarity of the SAM. The advent of satellite remote sensing in the late 1970s enabled the continuous observation of sea ice distribution in remote and harsh polar environments. Since 1979, the Antarctic SIE had shown a weak but significant positive trend until 2015, when it unexpectedly declined by∼50% with no discernible trend in subsequent years.
The researchers examined the monthly (September to February) and seasonal(spring and summer)sea ice variability in response to climate changes and polar vortex variability. They also studied atmospheric variables to determine their fidelity to the sea ice. The study analysed sea ice data from multichannel passive microwave satellites since the late 1970s.
The record low of February 2022 is linked to physical forcings, including monthly and seasonal variability. The deepening of the ASL has been identified with the strong northerly winds across the ABS and the Weddell Sea sectors, resulting in sea ice retreat. Wind-driven positive sea ice anomalies were observed in sectors with increasing southerly winds.
The lowest Antarctic sea ice record in February 2022 resulted from the long months of sea ice retreat induced by the cumulative response of the positive SAM and the deepening of the ASL. The atmospheric temperature and GPH anomaly also revealed evidence of warming at the surface, extending from the upper to the lower atmosphere and from the equator to the higher latitudes.
Due to the regional nature of Antarctic sea ice variability, small changes in atmospheric circulation in any sector may impact the SIE for the entire Southern Ocean. The study’s findings indicate that ASL and SAM play a more significant role in controlling sea ice variability in East Antarctica and the Weddell Sea during the ice retreat phase.
The study may help understand the role of atmospheric circulation and climate variability responsible for specific short-term events of low Antarctic sea ice. It may also provide insights into how Antarctic sea ice evolved before the satellite era and how it may vary in future.
The research team comprised Juhi Yadav (National Centre for Polar and Ocean Research, Ministry of Earth Sciences &Department of Marine Geology, Mangalore University, Mangalore); Avinash Kumar; and Rahul Mohan (both from NCPOR). The study has been published in Environmental Research Communications, an open-access journal. (India Science Wire)