A group of trees that grow fast, live long lives and reproduce slowly account for the bulk of the biomass and carbon storage in some tropical rainforests, a team of scientists says in a paper published this week in the journal Science. The finding that these trees, called long-lived pioneers, play a much larger role in carbon storage than previously thought may have implications in efforts to preserve forests as a strategy to fight climate change.
© Christian Ziegler | Long-living tropical trees play an outsized role in carbon storage

"People have been arguing about whether these long-lived pioneers contribute much to
  storage over the long term," said Caroline Farrior, an assistant professor of integrative biology at The University of Texas at Austin and a primary investigator on the study. "We were surprised to find that they do."
It is unclear the extent to which  can help soak up excess carbon dioxide in the atmosphere produced by burning fossil fuels. Nonetheless, the new study provides insights into the role of different species of  in carbon storage.
Using more than 30 years' worth of data collected from a tropical rainforest in Panama, the team has uncovered some key traits of trees that, when integrated into computer models related to , will improve the models' accuracy. With the team's improved , the scientists plan to begin answering questions about what drives forest composition over time and what factors affect carbon storage.
Most existing Earth system models used to forecast global climate decades from now, including those used by the Intergovernmental Panel on Climate Change, representing the trees in a forest as all basically the same.

Long-living tropical trees play outsized role in carbon storage
The team found that composition of a tropical rainforest over time depends on how each tree species balances two different sets of trade-offs: growth versus survival (for example, one type of tree might grow fast but die young) and stature versus reproduction (another might grow tall but reproduce leisurely). The team also discovered that the nearly 300 unique tree species that live on Barro Colorado Island in Panama (gray dots) can be represented in their computer model by just five functional groups and still produce accurate forecasts of tree composition and forest biomass over time. Credit: University of Texas at Austin/German Centre for Integrative Biodiversity Research (iDiv)
"This analysis shows that that is not good enough for  and provides a way forward," Farrior said. "We show that the variation in tropical forest species' growth, survival and reproduction is important for predicting forest ."
The project was led by Nadja RĂ¼ger, a research fellow at the German Centre for Integrative Biodiversity Research (iDiv), Halle-Jena-Leipzig.
In addition to the finding of long-lived pioneers, the team found the composition of tropical forest over time depends on how each tree species balances two different sets of trade-offs: growth versus survival (for example, one type of tree might grow fast but die young) and stature versus reproduction (another might grow tall but reproduce leisurely). Plotting every species as a point on a graph based on where they fall along these two different axes allowed the scientists to have a more sophisticated and accurate model than prior ones, which usually focused exclusively on the first of these two trade-offs or parametrized the groups by different means.
"To really appreciate that there is this second trade-off between stature and reproduction and that it's important in old-growth forests, is a big deal biologically," Farrior said.

Long-living tropical trees play outsized role in carbon storage
Around 300 tree species grow in 50 hectares of old-growth forest at Barro Colorado Island, Panama. Credit: Christian Ziegler
The team also discovered that the nearly 300 unique tree species that live on Barro Colorado Island, which sits in the middle of the Panama Canal, can be represented in their  by just five functional groups and still produce accurate forecasts of tree composition and forest biomass over time.
It's not possible to directly verify the forecasts of a forest model in future decades. So the researchers did the next best thing: They seeded their model with  composition data collected at their site in Panama during the 1980s and then ran the model forward to show that it accurately represents the changes that occurred from then until now. This is called "hindcasting."
Next, they plan to explore how a warming world might benefit trees with certain traits over others, shifting  and the potential of forests to store carbon.
"One of the biggest unknowns in climate forecasting is: What are trees going to do?" said Farrior. "We really need to get a handle on that if we're going to accurately predict how climate will change and manage forests. Right now, they're absorbing some of the excess carbon we're producing and delaying  change, but will they keep doing it?"
This article was originally published by the University of Texas at Austin.
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