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New research helps solve the riddle of the ocean carbon conundrum

About a quarter of the carbon dioxide we release each year ends up in the ocean, but how it happens is still not fully understood

Date:
March 1, 2016
Source:
University of Exeter
Summary:
Initially, the fact that the oceans are absorbing a significant amount of the carbon dioxide we pump into the atmosphere by burning biomass and fossil fuels would appear to be a good thing. However, as more carbon dioxide dissolves into the oceans, it changes the pH of the seawater (a process called ocean acidification), making it difficult for some marine life to survive.
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About a quarter of the carbon dioxide we release each year into the atmosphere ends up in the ocean, but how it happens is still not fully understood. The Sentinel-3A satellite is poised to play an important role in shedding new light on this exchange.

Initially, the fact that the oceans are absorbing a significant amount of the carbon dioxide we pump into the atmosphere by burning biomass and fossil fuels would appear to be a good thing. However, as more carbon dioxide dissolves into the oceans, it changes the pH of the seawater (a process called ocean acidification), making it difficult for some marine life to survive.

Monitoring and understanding the carbon cycle is important because carbon is the fundamental building block of all living organisms. The carbon cycle, the process of carbon moving between the oceans, atmosphere, land and ecosystems helps to modulate and control our climate.

Over the last four years an international team of scientists and engineers have been using satellites along with measurements from ships and pioneering cloud computing techniques to study the carbon dioxide in our oceans.

The team, led by Heriot-Watt University and the University of Exeter in the UK, have shown that satellite measurements together with ship measurements, can be used to study how carbon dioxide is transferred from the atmosphere into the oceans.

Their new work, published in the Journal of Atmospheric and Oceanic Technology, reveals that the seas around Europe absorb an astonishing 24 million tonnes of carbon each year. This is equivalent in weight to two million double decker buses or 72,000 Boeing 747s.

The team have made their data and cloud computing tools, the 'FluxEngine', available to the international scientific community so that other groups can analyse the data for themselves.

They hope that making tools like this available to everyone will improve the transparency and traceability of climate studies. It should also help to accelerate scientific advancement in this important area.

Jamie Shutler from the University of Exeter's in the Centre for Geography, Environment and Society, based on the Penryn Campus, added, "The information we are gathering using satellites is essential for monitoring our climate, but these observations are not always easily available for other scientists to use. This new development means that anyone can use our cloud tools and data to support their own research."

They are also now looking to Europe's Copernicus Sentinel satellites to provide vital information for this area of research.

Sentinel-3A was launched on 16 February and once commissioned for service it will measure the temperature of the sea surface, currents, winds, waves and other biochemical factors.

The unique aspect of Sentinel-3A is that its instruments make simultaneous measurements, providing overlapping data products that carry vital information to estimate carbon dioxide fluxes.

To calculate this movement (flux) of gases between the ocean and the atmosphere, it is necessary to know the solubility of carbon dioxide in the seawater, together with the speed of gas transfer. Importantly, the solubility is determined by a combination of sea-surface temperature and salinity, while the ocean surface wind and wave environment govern the speed at which carbon dioxide is transferred.

While satellites enable us to easily monitor the global oceans, shipboard measurements remain essential, as we can't monitor everything from space.

All this information from just one satellite makes the Sentinel-3 mission a near-perfect tool to estimate the exchange of carbon dioxide between the atmosphere and the global ocean, as well as seasonal, year-to-year and regional patterns in the exchange.

ESA's Sentinel-3 mission scientist, Craig Donlon, said, "The use of satellite data to provide a more informed and complete set of baseline data is helping to improve our understanding of carbon cycling.

"The ability for individual scientists to run and rerun their own flux calculations is a new and powerful way of working together in an open science world."

Andy Watson, from the University of Exeter's Geography Department, commented, "Good knowledge of the ocean uptake and release of carbon dioxide is essential for predicting climate change. Eventually, most of the carbon dioxide we release will find its way into the oceans.

"This project will provide the most accurate estimates that we have and is accessible to anyone."


Story Source:

Materials provided by University of Exeter. Note: Content may be edited for style and length.


Journal Reference:

  1. Jamie D. Shutler, Peter E. Land, Jean-Francois Piolle, David K. Woolf, Lonneke Goddijn-Murphy, Frederic Paul, Fanny Girard-Ardhuin, Bertrand Chapron, Craig J. Donlon. FluxEngine: A flexible processing system for calculating atmosphere-ocean carbon dioxide gas fluxes and climatologies. Journal of Atmospheric and Oceanic Technology, 2015; 151208152511003 DOI: 10.1175/JTECH-D-14-00204.1

Cite This Page:

University of Exeter. "New research helps solve the riddle of the ocean carbon conundrum." ScienceDaily. ScienceDaily, 1 March 2016. <www.sciencedaily.com/releases/2016/03/160301114721.htm>.
University of Exeter. (2016, March 1). New research helps solve the riddle of the ocean carbon conundrum. ScienceDaily. Retrieved November 15, 2024 from www.sciencedaily.com/releases/2016/03/160301114721.htm
University of Exeter. "New research helps solve the riddle of the ocean carbon conundrum." ScienceDaily. www.sciencedaily.com/releases/2016/03/160301114721.htm (accessed November 15, 2024).

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