06.13.17

If a Tree Falls in the Amazon

For the first time, scientists pinpointed how often storms topple trees, helping to predict how changes in Amazonia affect the world.

Click to enlarge photo. Enlarge Photo

For the first time, scientists determined the annual occurrence of windthrow events (solid and dashed lines representing different plottings of the events) in central Amazonia over a decade, plotted against annual rainfall (gray bars, millimeters per year). La Niña years highlighted in blue; El Niño years highlighted in red.

The Science

Gaps of uprooted or broken trees in Amazonia have cascading consequences, from local farm productivity to global carbon storage. Severe rain or thunderstorms with descending winds, expected to become more frequent with climate change, cause these gaps. For the first time, researchers show how the gaps vary across seasons and years in central Amazonia (Brazil). They found the trees break or fall more often between September and February. They also found that gaps were driven by storms forming in southern Amazonia and moving northeast.

The Impact

These results will improve representations of tree mortality in Earth system models. In particular, the results will improve the Accelerated Climate Modeling for Energy Land Model. These models help scientists understand how strong storms affect tropical forests. These forests absorb carbon dioxide from the atmosphere and impact the Earth’s overall energy balance.  Understanding tree death events is important given the increasing occurrences of El Niño events.

Summary

Gaps or broken trees, known as windthrows, are a common form of tree mortality in Amazonia. Windthrows affect forest dynamics and carbon storage, yet how windthrows vary over time has not been investigated. For the first time, researchers measured the seasonal and interannual variability of windthrows, focusing on an area in central Amazonia (Brazil). The team used Landsat images from 1998 through 2010 to detect windthrows, based on their shape and spectral characteristics. They found that windthrows occur every year but were more frequent between September and February. The team found that complex, organized downward rain and thunderstorms embedded in larger systems, such as squall lines, can cause windthrows. Also, they found that southerly squall lines (that move from southwest to northeast) happened more often than previously stated at the ~50-year interval. Looking across years, the team did not find a link between the El Niño-Southern Oscillation and windthrows.

Contact

BER PM
Renu Joseph
Renu.Joseph@science.doe.gov, 301-903-9237

Dan Stover
Daniel.Stover@science.doe.gov, 301-903-0289

PI Contact
William J. Riley
Lawrence Berkeley National Laboratory
wjriley@lbl.gov

Funding

This research was funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research under contract DE-AC02-05CH11231 as part of the Next-Generation Ecosystem Experiments–Tropics project and Regional and Global Climate Modeling program.

Publications

R.I. Negron-Juarez, H.S. Jenkins, C.F.M. Raupp, W.J. Riley, L.M. Kueppers, D. Magnabosco Marra, G.H.P.M. Ribeiro, M.T.F. Monterio, L.A. Candido, J.Q. Chambers, and N. Higuch, “Windthrow variability in Central AmazoniaExternal link.” Atmosphere 8(2), 28 (2017). [DOI: 10.3390/atmos8020028]

Highlight Categories

Program: BER, CESD

Performer/Facility: University, DOE Laboratory

Last modified: 9/7/2017 7:27:31 AM