Tropical forests can handle the heat, up to a point
Tropical forests face an uncertain future under climate change, but new research published in Science suggests they can continue to store large amounts of carbon in a warmer world, if countries limit greenhouse gas emissions.
The world鈥檚 tropical forests store a quarter-century worth of fossil fuel emissions in their trees alone. There are fears that global heating can reduce this store if tree growth reduces or tree death increases, accelerating climate change.
Dr Simon Willcock of 麻豆传媒高清版鈥檚 School of Natural Sciences was one of an international research team who measured over half a million trees in 813 forests across the tropics to assess how much carbon is stored by forests growing under different climatic conditions today.
The team reveal that tropical forests continue to store high levels of carbon under high temperatures, showing that in the long run these forests can handle heat up to an estimated threshold of 32 degrees Celsius in daytime temperature.
Yet this positive finding is only possible if forests have time to adapt, they remain intact, and if global heating is strictly limited to avoid pushing global temperatures into conditions beyond the critical threshold.
Dr Simon Willcock said: 鈥淭ropical forests are one of the world鈥檚 most important ecosystems. Sometimes referred to as the 鈥榣ungs of the planet鈥, they help stabilise the world鈥檚 climate, as well as providing a home to about half of the plants and animals on Earth. As such, understanding the impact of climate change on these ecosystems is vital.鈥
Lead author Dr Martin Sullivan, from the University of Leeds and Manchester Metropolitan University, said: 鈥淥ur analysis reveals that up to a certain point of heating tropical forests are surprisingly resistant to small temperature differences. If we limit climate change they can continue to store a large amount of carbon in a warmer world.
鈥淭he 32 degree threshold highlights the critical importance of urgently cutting our emissions to avoid pushing too many forests beyond the safety zone.
鈥淔or example, if we limit global average temperatures to a 2掳C increase above pre-industrial levels this pushes nearly three-quarters of tropical forests above the heat threshold we identified. Any further increases in temperature will lead to rapid losses of forest carbon.
鈥淓ach degree increase in temperature would release 51 billion tonnes of CO2 from tropical forests to the atmosphere鈥.
Forests release carbon dioxide into the atmosphere when the amount of carbon gained by tree growth is less than that lost through tree mortality and decay.
The study is the first to analyse long-term climate sensitivity based on direct observation of whole forests across the topics. The research suggests that over the long-term temperature is has the greatest effect on forest carbon stocks by reducing growth, with drought killing trees the second key factor.
The researchers conclude that tropical forests have long-term capacity to adapt to some climate change, in part because of their high biodiversity, as tree species better able to tolerate new climatic conditions grow well and replace less well-adapted species, over the long-term.
But maximizing this potential climate resilience depends on keeping forests intact.
Co-author Professor Beatriz Marimon from the State University of Mato Grosso in Brazil studies some of the world鈥檚 hottest tropical forests in central Brazil. She noted: 鈥淥ur results suggest that intact forests are able to withstand some climate change. Yet these heat-tolerant trees also face immediate threats from fire and fragmentation.
鈥淎chieving climate adaptation means first of all protecting and connecting the forests that remain.鈥
Professor Marimon notes the clear limits to adaptation. 鈥淭he study indicates a heat threshold of 32 degrees Celsius in daytime temperature. Above this point tropical forest carbon declines more quickly with higher temperatures, regardless of which species are present.鈥
The insights into how the world鈥檚 tropical forests respond to climate were only possible with decades of careful fieldwork, often in remote locations. The global team of 225 researchers combined forests observations across South America (), Africa () and Asia (). In each monitoring plot the diameter of each tree and its height was used to calculate how much carbon they stored. Plots were revisited every few years to see how much carbon was being taken in, and how long it was stored before trees died.
To calculate changes in carbon storage required identifying nearly 10,000 tree species and over two million measurements of tree diameter, across 24 tropical countries. According to Professor Simon Lewis of the University of Leeds and University College London: 鈥淭he amount of carbon absorbed and stored by forests is a crucial element in how the Earth responds to climate change.鈥
鈥淭he study underlines why long-term research collaboration is essential for understanding the effects of environmental change. Scientists need to work together more than ever, as monitoring the health of our planet鈥檚 great tropical forests is vital for all of us.鈥
Cutting carbon emissions enough to keep forests within the safety zone will be very challenging. 麻豆传媒高清版 author Professor Oliver Phillips of the University of Leeds said: 鈥淜eeping our planet and ourselves healthy has never been more important. Right now, humanity has a unique opportunity to make the transition toward a stable climate.
鈥淏y not simply returning to 鈥榖usiness as usual鈥 after the current crisis we can ensure tropical forests remain huge stores of carbon. Protecting them from climate change, deforestation and wildlife exploitation needs to be front and centre of our global push for biosecurity.
鈥淚magine if we take this chance to reset how we treat our Earth. We can keep our home cool enough to protect these magnificent forests - and keep all of us safer.鈥
Further information:
The paper Long-term thermal sensitivity of Earth鈥檚 tropical forests is published in Science 22 May 2020
Publication date: 22 May 2020