NASA Earth Observatory image by Jesse Allen using
Landsat data from USGS
Runoff from one of North America’s largest rivers is driving intense carbon
dioxide emissions in the Arctic Ocean.
When it comes to influencing
climate change, the world’s smallest ocean punches above its weight. It’s been
estimated that the cold waters of the Arctic absorb as much as 180 million
metric tons of carbon per year – more than three times what New York City emits
annually – making it one of Earth’s critical carbon sinks. But recent findings
show that thawing permafrost and carbon-rich runoff from Canada’s Mackenzie
River trigger part of the Arctic Ocean to release more carbon dioxide (CO2)
than it absorbs.
The study, published earlier this year, explores how scientists are using
state-of-the-art computer modeling to study rivers such as the Mackenzie, which
flows into a region of the Arctic Ocean called the Beaufort Sea. Like many
parts of the Arctic, the Mackenzie River and its delta have faced significantly
warmer temperatures in recent years across all seasons, leading to more melting
and thawing of waterways and landscapes.
In this marshy corner of Canada’s
Northwest Territories, the continent’s second largest river system ends a
thousand-mile journey that begins near Alberta. Along the way, the river acts
as a conveyor belt for mineral nutrients as well as organic and inorganic
matter. That material drains into the Beaufort Sea as a soup of dissolved
carbon and sediment. Some of the carbon is eventually released, or outgassed,
into the atmosphere by natural processes.
Scientists have thought of the
southeastern Beaufort Sea as a weak-to-moderate CO2 sink, meaning it absorbs
more of the greenhouse gas than it releases. But there has been great
uncertainty due to a lack of data from the remote region.
To fill that void, the study team
adapted a global ocean biogeochemical model called ECCO-Darwin, which was
developed at NASA’s Jet Propulsion Laboratory in Southern California and the
Massachusetts Institute of Technology in Cambridge. The model assimilates
nearly all available ocean observations collected for more than two decades by
sea- and satellite-based instruments (sea level observations from the
Jason-series altimeters, for example, and ocean-bottom pressure from the GRACE and GRACE Follow-On missions).
Like a conveyer belt of carbon, the Mackenzie River, seen here in 2007 from NASA’s Terra satellite, drains an area of almost 700,000 square miles (1.8 million square kilometers) on its journey north to the Arctic Ocean. Some of the carbon originates from thawing permafrost and peatlands. NASA/GSFC/METI/ERSDAC/JAROS, and U.S./Japan ASTER Science Team
The scientists used the model to simulate the discharge of fresh water and
the elements and compounds it carries – including carbon, nitrogen, and silica
– across nearly 20 years (from 2000 to 2019).
The researchers, from France, the
U.S., and Canada, found that the river discharge was triggering such intense
outgassing in the southeastern Beaufort Sea that it tipped the carbon balance,
leading to a net CO2 release of 0.13 million metric tons per year – roughly
equivalent to the annual emissions from 28,000 gasoline-powered cars. The
release of CO2 into the atmosphere varied between seasons, being more
pronounced in warmer months, when river discharge was high and there was less
sea ice to cover and trap the gas.
Ground Zero
for Climate Change
Scientists have for decades studied
how carbon cycles between the open ocean and atmosphere, a process called
air-sea CO2 flux. However, the observational record is sparse along the coastal
fringes of the Arctic, where the terrain, sea ice, and long polar nights can
make long-term monitoring and experiments challenging.
“With our model, we are trying to
explore the real contribution of the coastal peripheries and rivers to the
Arctic carbon cycle,” said lead author Clément Bertin, a scientist at Littoral
Environnement et Sociétés in France.
Such insights are critical because
about half of the area of the Arctic Ocean is composed of coastal waters, where
land meets sea in a complex embrace. And while the study focused on a
particular corner of the Arctic Ocean, it can help tell a larger story of
environmental change unfolding in the region.
Since the 1970s, the Arctic has
warmed at least three times faster than anywhere else on Earth, transforming
its waters and ecosystems, the scientists said. Some of these changes promote
more CO2 outgassing in the region, while others lead to more CO2 being
absorbed.
For example, with Arctic lands
thawing and more snow and ice melting, rivers are flowing more briskly and
flushing more organic matter from permafrost and peatlands into the ocean. On
the other hand, microscopic phytoplankton floating near the ocean surface are
increasingly taking advantage of shrinking sea ice to bloom in the newfound open water and
sunlight. These plantlike marine organisms capture and draw down atmospheric
CO2during photosynthesis. The ECCO-Darwin model is being used to study these
blooms and the ties between ice and life in the Arctic.
Scientists are tracking these large and seemingly small changes in the Arctic and beyond because our ocean waters remain a critical buffer against a changing climate, sequestering as much as 48% of the carbon produced by burning fossil fuels.
Source: As the Arctic Warms, Its Waters Are Emitting Carbon - NASA
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