Trees Are Biggest Methane Vents in Wetland Areas

Most of the methane gas emitted from Amazon wetlands regions is vented into the atmosphere via tree root systems with significant emissions occurring even when the ground is not flooded, say researchers at the University of Birmingham.

In a study published in the Royal Society journal, Philosophical Transactions A, the researchers have found evidence that far more methane is emitted by trees growing on floodplains in the Amazon basin than soil or surface water, which occurs in both wet and dry conditions.

Methane is the second most important greenhouse gas, and much of our atmospheric methane comes from wetlands. Much research is being carried on into exactly how much methane is emitted via this route. Still, models typically assume that the gas is only produced when the ground is completely flooded and underwater.

In wetland areas where there are no trees, methane would typically be consumed by the soil on its way to the surface. Still, in forested wetland areas, the researchers say the tree roots could be acting as a transport system for the gas, up to the surface where it vents into the atmosphere from the tree trunks.

Methane can escape via this route even when produced several meters below ground level in soil and water. This would mean that existing models could significantly underestimate the likely extent of methane emissions in wetland areas such as the Amazon basin.

To test the theory, the team carried out measurements across three plots on the floodplains of three major rivers in the central Amazon basin. The same trees were monitored at each plot at four-time points over the year to capture their response to changing water levels associated with the annual flood. Methane emissions were measured using a portable greenhouse gas analyser, and then calculations were done to scale the findings across the Amazon basin.

Overall, the team estimates that nearly half of global tropical wetland methane emissions are funnelled out by trees. The unexpected result is that trees are also crucial for emissions when the floodplain water table sits below the soil’s surface.

In the School of Geography, Earth and Environmental Sciences at the University of Birmingham (and the Birmingham Institute of Forest Research), Lead author, Professor Vincent Gauci, says: ‘Our results show that current global emissions estimates are missing a crucial piece of the picture. We now need to develop models and methods that consider the significant role of methane emission.’

The team was led by the University of Birmingham and included researchers from the University Federal of Rio de Janeiro, the Met Office Hadley Centre, Lancaster University, and Linköping University. It was funded by the Natural Environment Research Council (part of UK Research and Innovation), the Newton Fund, the Royal Society and Brazilian funding agencies CNPq, CAPES and FAPERJ.