Marine phytoplankton releases sulphur compounds into the atmosphere that contribute to cooling the planet. But ocean acidification could hinder this process. Photo: Wim van Egmond / Visuals Unlimited / SPL

By Eliot Barford
25 August 2013 (Nature) – The slow and inexorable increase in the oceans’ acidity as they soak up carbon dioxide from the atmosphere could itself have an effect on climate and amplify global warming, according to a new study. Acidification would lead certain marine organisms to emit less of the sulphur compounds that help to seed the formation of clouds and so keep the planet cool. Atmospheric sulphur, most of which comes from the sea, is a check against global warming. Phytoplankton — photosynthetic microbes that drift in sunlit water — produces a compound called dimethylsulphide (DMS). Some of this enters the atmosphere and reacts to make sulphuric acid, which clumps into aerosols, or microscopic airborne particles. Aerosols seed the formation of clouds, which help cool the Earth by reflecting sunlight. James Lovelock and colleagues proposed in the 1980s that DMS could provide a feedback mechanism limiting global warming1, as part of Lovelock’s ‘Gaia hypothesis’ of a self-regulating Earth. If warming increased plankton productivity, oceanic DMS emissions might rise and help cool the Earth.  More recently, thinking has shifted towards predicting a feedback in the opposite direction, because of acidification. As more CO2 enters the atmosphere, some dissolves in seawater, forming carbonic acid. This is decreasing the pH of the oceans, which is already down by 0.1 pH units on pre-industrial times, and could be down by another 0.5 in some places by 2100. And studies using ‘mesocosms’ — enclosed volumes of seawater — show that seawater with a lower pH produces less DMS2. On a global scale, a fall in DMS emissions due to acidification could have a major effect on climate, creating a positive-feedback loop and enhancing warming. Katharina Six at the Max Planck Institute for Meteorology in Hamburg, Germany, and her colleagues have applied these mesocosm data to a global climate model developed at their institute. In a ‘moderate’ scenario described by the Intergovernmental Panel on Climate Change, which assumes no reductions in emissions of heat-trapping gases, global average temperatures will increase by 2.1 to 4.4 °C by the year 2100. Adding in the effects of acidification on DMS, which the team calculated using three different estimates of the strength of the link between pH and DMS production, led to additional increases ranging between 0.23 and 0.48 °C. Their paper is published in Nature Climate Change today3. “The result in itself doesn’t surprise me too much,” says Michael Steinke, a researcher at the University of Essex. But he thinks that incorporating such results into predictive global models is important. “This is something that hasn’t really been done very much yet,” he says However, Steinke points out a recent study of his own4 indicating that oceanic DMS emissions might be more affected by increasing temperature than acidity. Warmer waters tend to make more DMS, so it could increase overall in future. The new study does take warming into account, but Steinke emphasizes that the effect of acidification on DMS production is better understood than that of other human-induced environmental changes. [more]

Rising ocean acidity will exacerbate global warming