The Greenland Ice Sheet is melting faster today than it did only a few years ago. The reason: it’s not just melting on the surface – but underwater, too. AWI researchers have now found an explanation for the intensive melting on the Greenland Ice Sheet underside and published their findings in the journal Nature Geoscience.
The glaciers are melting rapidly: Greenland’s ice is now melting seven times faster than in the 1990s – an alarming discovery, since climate change will likely intensify this melting in the future, causing the sea level to rise more rapidly. Accordingly, researchers are now working to better understand the underlying mechanisms of this melting. Ice melts on the surface because it is exposed to the sun and rising temperatures. But it has now also begun melting from below – including in northeast Greenland, which is home to several ‘ice tongues’. Each tongue is a strip of ice that has slid down into the ocean and floats on the water – without breaking off from the land ice. The longest ice tongue, part of the ‘79° North Glacier’, is an enormous 80 km long. Over the past 20 years, it has experienced a dramatic loss of mass and thickness, because it’s been melting not just on the surface, but also and especially from below.
Too much heat from the ocean
A team led by oceanographer Dr Janin Schaffer from the Alfred Wegener Institute, Helmholtz Centre for Polar and Marine Research (AWI) in Bremerhaven has now identified the source of this intense underwater melting. The conclusions of their study, which the experts have just released in the journal Nature Geoscience, are particularly unsettling because the melting phenomenon they discovered isn’t unique to the 79° North Glacier, which means it could produce similar effects elsewhere. For the purposes of the study, the researchers conducted the first extensive ship-based survey of the ocean floor near the glacier, which revealed the presence of a two-kilometre-wide trough, from the bottom of which comparatively warm water from the Atlantic is channelled directly toward the glacier. But that’s not all: in the course of a detailed analysis of the trough, Janin Schaffer spotted a bathymetric sill, a barrier that the water flowing over the seafloor has to overcome. Once over the hump, the water rushes down the back of the sill – and under the ice tongue. Thanks to this acceleration of the warm water mass, large amounts of heat from the ocean flow past the tongue every second, melting it from beneath. To make matters worse, the layer of warm water that flows toward the glacier has grown larger: measured from the seafloor, it now extends 15 metres higher than it did just a few years ago. “The reason for the intensified melting is now clear,” Schaffer says. “Because the warm water current is larger, substantially more warmth now makes its way under the ice tongue, second for second.”
Other regions are also affected
In order to determine whether the phenomenon only manifests at the 79° North Glacier or also at other sites, the team investigated a neighbouring region on Greenland’s eastern coast, where another glacier, the Zachariæ Isstrøm, juts out into the sea, and where a large ice tongue had recently broken off from the mainland. Working from the surface of an ice floe, the experts measured water temperatures near the ocean floor. According to Schaffer: “The readings indicate that here, too, a bathymetric sill near the seafloor accelerates warm water toward the glacier. Apparently, the intensive melting on the underside of the ice at several sites throughout Greenland is largely produced by the form of the seafloor.” These findings will ultimately help her more accurately gauge the total amount of meltwater that the Greenland Ice Sheet loses every year.
Original Study
Janin Schaffer, Torsten Kanzow, Wilken-Jon von Appen, Luisa von Albedyll, Jan Erik Arndt and David H. Roberts, „Bathymetry constrains ocean heat supply to Greenland’s largest glacier tongue”, Nature Geoscience, 3 February 2020, DOI: 10.1038/s41561-019-0529-x
The Arctic and the All-Atlantic Ocean Research Cooperation
The Arctic is undergoing the most rapid changes in the climate system worldwide. Such changes have global and regional implications including extreme weather, sea-level change, coastal erosion, natural hazards and changes in the ecosystem. Moreover, these changes impact severely on people´s living conditions in the Arctic. In 2019, the Arctic received plenty of attention after the release of the IPCC “Special Report on the Ocean and Cryosphere in a Changing Climate”. In order to ensure sustainable development in the Arctic, it is necessary to collect more data and build up knowledge of its climate and environment.
The All-Atlantic Ocean Research Community pays particular attention to the Arctic, namely through three of our six key areas of cooperation:
Climate Variability
It is long known that the ocean’s physical and biological processes influence Earth’s weather and climate. But changes are occurring: ocean acidification, sea-level rise, flooding and extreme weather, climate change; which are impacting countries and communities, as well as ocean’s processes and ecosystems themselves. There is a need to work together to better understand and predict climate variability to ensure humankind’s well-being and build a sustainable blue economy.
Ocean Observation
Earth is really an ocean planet, as the world’s ocean covers more than 70% of the Earth’s surface. Yet a whopping 95% of the ocean is unexplored! Even with all the existing technologies – satellites, buoys, underwater vehicles, vessels – the current ocean observation, forecasting and monitoring systems are fragmented and their sustainability is a concern for most. There is a recognised need for sustained long-term observations.
Polar Research
Research in the polar regions is relevant and important for all of us and our everyday life, because of its profound effect on the Earth’s climate and ocean systems. Polar science has therefore the potential to support the sustainable use of resources, the protection of the planet and benefit humanity.
“What happens in the Arctic does not stay in the Arctic”.