A Rapidly Changing Arctic: Significantly More Carbon & Nutrients to North Pole

GEOTRACES Research Arctic

An international team of scientists aboard the US Coast Guard Cutter Healy and the German research icebreaker Polarstern met at the North Pole in 2015 to survey elements in the Arctic Ocean as part of the international GEOTRACES research program. Credit: Stefan Hendricks, Alfred Wegener Institute

Shelf sediments, freshwater runoff from rivers brings more carbon, nutrients to North Pole.

  • Trace elements may increase with future Arctic melt releasing dissolved organic matter from permafrost thaw.
  • Nutrient levels and productivity may increase in the Arctic, but loss of ice cover will continue to worsen overall warming as more heat is absorbed from the atmosphere.

A new study by researchers at Woods Hole Oceanographic Institution (WHOI) and their international colleagues found that freshwater runoff from rivers and continental shelf sediments are bringing significant quantities of carbon and trace elements into parts of the Arctic Ocean via the Transpolar Drift — a major surface current that moves water from Siberia across the North Pole to the North Atlantic Ocean.

In 2015, oceanographers conducting research in the Arctic Ocean as part of the International GEOTRACES program found much higher concentrations of trace elements in surface waters near the North Pole than in regions on either side of the current. Their results published this week in the Journal of Geophysical Research-Oceans.

A polar bear sighting off the U.S. Coast Guard Cutter Healy during the 2015 Arctic GEOTRACES expedition. The Arctic has experienced the highest degree of warming on the planet, causing sea ice to thin and recede. The region’s iconic polar bears rely on sea ice to hunt, travel and mate.

“Many important trace elements that enter the ocean from rivers and shelf sediments are quickly removed from the water column,” explains WHOI marine chemist Matthew Charette, lead author of the study. “But in the Arctic they are bound with abundant organic matter from rivers, which allows the mixture to be transported into the central Arctic, over 1,000 kilometers from their source.”

Trace elements, like iron, form essential building blocks for ocean life. As the Arctic warms and larger swaths of the ocean become ice-free for longer periods of time, marine algae are becoming more productive. A greater abundance of trace elements coming from rivers and shelf sediments can lead to increases in nutrients reaching the central Arctic Ocean, further fueling algal production.

“It’s difficult to say exactly what changes this might bring,” says Charette. “but we do know that the structure of marine ecosystems is set by nutrient availability.”

Nutrients fuel the growth of phytoplankton, a microscopic algae that forms the base of the marine food web. Generally speaking, more phytoplankton brings more zooplankton — small fish and crustaceans, which can then be eaten by top ocean predators like seals and whales.

Higher concentrations of trace elements and nutrients previously locked up in frozen soils (permafrost) are expected to increase as more river runoff reaches the Arctic, which is warming at a much faster rate than most anywhere else on Earth.  While an increase in nutrients may boost Arctic marine productivity, Charette cautions that the continued loss of sea ice will further exacerbate climate warming, which will impact ecosystems more broadly.

“The Arctic plays an important role in regulating Earth’s climate, with the ice cover reflecting sunlight back to space, helping to mitigate rising global temperatures due to greenhouse gas emissions,” he adds. “Once the ice is gone, the Arctic Ocean will absorb more heat from the atmosphere, which will only make our climate predicament worse.”

Reference: “The Transpolar Drift as a Source of Riverine and Shelf‐Derived Trace Elements to the Central Arctic Ocean” by Matthew A. Charette, Lauren E. Kipp, Laramie T. Jensen, Jessica S. Dabrowski, Laura M. Whitmore, Jessica N. Fitzsimmons, Tatiana Williford, Adam Ulfsbo, Elizabeth Jones, Randelle M. Bundy, Sebastian M. Vivancos, Katharina Pahnke, Seth G. John, Yang Xiang, Mariko Hatta, Mariia V. Petrova, Lars-Eric Heimbürger-Boavida, Dorothea Bauch, Robert Newton, Angelica Pasqualini, Alison M. Agather, Rainer M. W. Amon, Robert F. Anderson, Per S. Andersson, Ronald Benner, Katlin L. Bowman, R. Lawrence Edwards, Sandra Gdaniec, Loes J. A. Gerringa, Aridane G. González, Mats Granskog, Brian Haley, Chad R. Hammerschmidt, Dennis A. Hansell, Paul B. Henderson, David C. Kadko, Karl Kaiser, Patrick Laan, Phoebe J. Lam, Carl H. Lamborg, Martin Levier, Xianglei Li, Andrew R. Margolin, Chris Measures, Rob Middag, Frank J. Millero, Willard S. Moore, Ronja Paffrath, Hélène Planquette, Benjamin Rabe, Heather Reader, Robert Rember, Micha J. A. Rijkenberg, Matthieu Roy-Barman, Michiel Rutgers van der Loeff, Mak Saito, Ursula Schauer, Peter Schlosser, Robert M. Sherrell, Alan M. Shiller, Hans Slagter, Jeroen E. Sonke, Colin Stedmon, Ryan J. Woosley, Ole Valk, Jan van Ooijen and Ruifeng Zhang, 8 April 2020, Geophysical Research-Oceans.
DOI: 10.1029/2019JC015920

Funding for Arctic GEOTRACES was provided by the U.S. National Science Foundation, Swedish Research Council Formas, French Agence Nationale de la Recherche and LabexMER, Netherlands Organization for Scientific Research, and Independent Research Fund Denmark. The Arctic GEOTRACES expeditions were supported by the captains and crew of the USCGC Healy and the R/V Polarstern.

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