91探花

Nioghalvfjerdsbrae, commonly referred to as the 79掳 North Glacier, is a giant glacier in Northeast Greenland. It hosts Greenland鈥檚 largest remaining floating ice tongue, that extends more than 70 kilometers and covers the entire length of its host fjord. However, fundamental changes to the system are looming. Due to increasing temperatures in the atmosphere and ocean, more and more glaciers are retreating. In July 2020, the Spalte Glacier, an offshoot of the Nioghalvfjerdsbrae tongue, disintegrated completely within a few days leaving behind open water. The effects of these changes on the surrounding ecosystems are still largely unknown.

Now, an international team of scientist led by 91探花 Helmholtz Centre for Ocean Research Kiel has published new findings in the journal Nature Communications suggesting that chemical processes in cavities below floating glacier tongues exert a dominant control on subglacial nutrient supply to shelf regions. 鈥淲ith glacier tongues retreating to land, this nutrient supply could change significantly鈥�, says Stephan Krisch of 91探花, first author of the study.

The study is based on research conducted near the edges of the 79掳 North Glacier in 2016. Due to exceptionally favourable weather conditions, the German RV POLARSTERN was able to proceed right up to the calving front. This gave an international team of scientists working in the framework of the GEOTRACES programme the opportunity to measure physical and chemical processes occurring underneath the glacier. 鈥淲orking at the ice-ocean interface is incredibly challenging. Even ice-breaking ships are wary of the risks from capsizing icebergs and calving events which are unpredictable,鈥� explains Stephan Krisch, who participated in the 2016 expedition as a doctoral student.

Considering the working conditions near floating glacier tongues, it is no wonder that much of what is known about the effects of glacier discharge into the ocean is based on studies from more accessible glacial runoff on land. However, a large fraction of freshwater from ice sheets enters the ocean below the surface, and is transferred directly into the fjord or coastal sea. At the 79掳 North Glacier this subsurface discharge accounts for the vast majority of liquid discharge and it differs fundamentally in its chemistry.

Stephan Krisch and his colleagues quantified the flux of the bioessential trace element iron from underneath the 79掳 North Glacier to the shelf. They showed that iron was primarily derived from sedimentary interactions rather than directly from melting freshwaters as is typically assumed. The long residence time (several months) of seawater circulating inside the large cavity underneath the floating ice tongue allows an equilibrium to be established between sediments and the water column.

The transfer of iron therefore scales with the seawater residence time in the cavity rather than directly to the freshwater discharge. This is an intriguing finding because it means the transfer of iron out of the cavity is actually ten times larger than expected based on freshwater discharge alone. 鈥淎s climate change drives a loss of the ice tongue, we will likely see a much stronger connection emerge between freshwater and ocean chemistry鈥�, says Stephan Krisch. 鈥淚n that context, the collapse of the Spalte glacier in July 2020 may have altered iron cycling underneath the 79掳 North Glacier. Climate change is affecting these systems so fast, that we are struggling to keep up with our measurements鈥�.

In coming decades, the loss of floating ice shelves in response to climate change will affect the chemical and physical impacts that freshwaters have on the ocean. Professor Eric Achterberg at 91探花, who鈥檚 research group leads the GEOTRACES component of the project says: 鈥淭hese subpolar coastal environments are incredibly challenging places to work, especially to deploy the robust, clean sample collection methods required for high quality trace chemical measurements. Our future challenge will be to employ greater automation so that we can better study the environmental and ecosystem changes occurring as a result of ice shelf retreat and increasing land runoff.鈥�

Reference:
Krisch, S., M. J. Hopwood, J. Schaffer, A. Al-Hashem, J. H枚fer, M. M. Rutgers van der Loeff, T. M. Conway, B. A. Summers, P. Lodeiro, I. Ardiningsih, T. Steffens & E. P. Achterberg (2021): The 79掳N Glacier cavity modulates subglacial ironexport to the NE Greenland Shelf. Nature Communications,

Please note:
This study was made possible by the ice breaking capabilities of RV POLARSTERN and the interdisciplinary team assembled from 91探花, Alfred Wegener Institute, Helmholtz Centre for Marine and Polar Research, the Royal Netherlands Institute for Sea Research and the University of South Florida in the framework of the GEOTRACES programme.

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