Plans to use marine microorganisms as a sink for atmospheric carbon dioxide appear to have suffered a setback. Early results of an experiment designed to test the concept indicate that the process is significantly less effective than originally thought — and may also have undesirable side effects.
If confirmed, the results, which are being prepared for submission to a number of journals, would weaken the argument that oceanic carbon sequestration can act as a significant component in controlling the build-up of greenhouse gases in the atmosphere.
“The experiment was a tremendous success at every level,” says Kenneth Coale of the Moss Landing Marine Laboratories near Monterey, California, who led the team of researchers, “but some of the results give us cause for concern.”
The team was investigating the effectiveness of iron fertilization, which involves adding iron sulphate to the ocean surface to encourage the growth of phytoplankton. These single-celled algae absorb carbon dioxide from the ocean, which in turn causes more of the gas to migrate from the atmosphere into the water. The huge algal blooms caused by the iron fertilization may then be eaten by other organisms or sink into the deep ocean, taking the carbon with them.
Coale and his team spent 28 days studying patches of iron sulphate spread on the ocean south of New Zealand. Known as the Southern Ocean Iron Fertilization Experiment (SOFeX), the project was the most comprehensive effort yet to study oceanic iron fertilization.
During the experiment, three research vessels dodged icebergs and ugly weather in a region chosen for its significant impact on natural sequestration of carbon dioxide from the atmosphere. Two of the research vessels — the Roger Revelle and the Melville — repeatedly spread an iron sulphate solution on the ocean surface. As a result, the team recorded a bloom of phytoplankton 200 kilometres long.
The researchers revealed their preliminary findings at a meeting of the American Geophysical Union (AGU) in San Francisco on 9–10 December. Although the bulk of the carbon stayed near the surface, Ken Buesseler, an oceanographer at Woods Hole Oceanographic Institution in Massachusetts, said that the experiment showed for the first time that carbon can be transported below 100 metres by iron fertilization.
But the process is not as efficient as predicted. The team's analysis indicates that one tonne of iron spread at the ocean surface could force 1,000 tonnes of carbon below 100 metres, Buesseler told the AGU meeting. Previous laboratory experiments had estimated that one tonne of iron would sink 100,000 tonnes of carbon. More carbon may sink over a longer period, he suggested, but longer experiments are needed to determine how much. “I'm not certain the oceans can ever solve our carbon dioxide problem,” says Coale.
Oliver Wingenter, a chemist at New Mexico Tech in Socorro, reported on the activity of other gases produced by phytoplankton. Wingenter found that emissions of methyl bromide, which can deplete the protective ozone layer at high altitude, increased sharply. And emissions of isoprene — a hydrocarbon that generates greenhouse gases at low altitude — rose “dramatically”, he says.
Kenneth Johnson, an oceanographer from Monterey Bay Aquarium Research Institute who was chief scientist on the Roger Revelle, says that these unintended consequences “aren't great” for the feasibility of using the technique on a large scale.
About this article
Iron Deficiency Induces a Partial Inhibition of the Photosynthetic Electron Transport and a High Sensitivity to Light in the Diatom Phaeodactylum tricornutum
Frontiers in Plant Science (2016)
Bioavailability and Dulability of the Iron Released from a Steelmaking Slag for Tow Thalassiosira Species
Microbial response to a mesoscale iron enrichment in the NE subarctic Pacific: Heterotrophic bacterial processes
Deep Sea Research Part II: Topical Studies in Oceanography (2006)
Responses of phytoplankton and heterotrophic bacteria in the northwest subarctic Pacific to in situ iron fertilization as estimated by HPLC pigment analysis and flow cytometry
Progress in Oceanography (2005)
Export fluxes of particulate organic carbon estimated from 234Th/238U disequilibrium during the Subarctic Pacific Iron Experiment for Ecosystem Dynamics Study (SEEDS 2001)
Progress in Oceanography (2005)