Researcher’s findings to help assess emissions
A study by a Stirling University academic has found that climate is the dominant driver in determining how quickly dead plants decompose.
Decaying dead plants and leaves, known as plant litter, release carbon into the atmosphere every year – six times more than all human emissions – and contribute around 10 per cent of the total amount of carbon in the atmosphere.
Although natural, any increase in their rate could further accelerate climate change.
But, according to research, the Stirling results allow scientists to make more accurate predictions on carbon emissions and climate change globally.
Lecturer in Soil Ecology at the University of Stirling, Dr François-xavier Joly, carried out the research at France’s University of Montpellier.
He said: “This research is important as it refines our understanding of one of the most important fluxes of carbon to the atmosphere and suggests that we may have been studying decomposition incorrectly in recent years.
“The carbon emitted to the atmosphere through decomposition accelerates climate change, so this improved understanding is vital to helping better predict future carbon emissions and climate scenarios in our changing world. Our specific findings might also help modellers to put more realistic parameters into their systems, and provide more accurate future climate predictions as a result.
“The more accurately we can predict how the natural process of dead plant material decomposition is responding to the ongoing climate change crisis, the better we can understand how its response may slow down or accelerate climate change in the years to come.”
The research team studied around 200 varying forest plots from six regions across Europe, from Spain to Finland, where they collected climatic, canopy, soil and litter quality data. Academics placed artificial plant litter like sheets of paper and sticks of wood to decompose in plots alongside the natural litter from the surrounding environment, for example, dead oak tree leaves in an oak tree forest, and measured their rate of decomposition over a year.
While the artificial plant litter, commonly used in studies of this kind, suggested a stronger control of smallscale environmental conditions on decomposition, the decomposition of the natural, so-called plant litter was largely controlled by large-scale climatic conditions.