1. Symbiotic N fixation is sufficient to support net aboveground biomass accumulation in a humid tropical forest
- Author
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E. N. J. Brookshire, Bryce Currey, Duncan N. L. Menge, Carlton Roberts, Nina Wurzburger, and Michael P. Oatham
- Subjects
0301 basic medicine ,geography ,Biogeochemical cycle ,Multidisciplinary ,geography.geographical_feature_category ,Ecosystem ecology ,lcsh:R ,Humid subtropical climate ,Biogeochemistry ,Tropics ,lcsh:Medicine ,Carbon sequestration ,Old-growth forest ,Sink (geography) ,Article ,03 medical and health sciences ,030104 developmental biology ,0302 clinical medicine ,Agronomy ,Element cycles ,Nitrogen fixation ,Environmental science ,lcsh:Q ,lcsh:Science ,030217 neurology & neurosurgery - Abstract
Symbiotic nitrogen (N) fixation has been shown to support carbon storage in young regenerating tropical forests, but N-fixing trees can also be strong competitors with non-fixing trees, making it unclear which mechanism drives long term patterns in biomass accretion. Many tropical forests have excess N, but factors such as rising atmospheric CO2 or selective cutting practices might induce additional N demand. Here we combine decades of stem inventory data, in-situ measures of symbiotic N fixation, and simulations of N demand to evaluate demographic and biogeochemical controls on biomass dynamics in legume-rich lowland forests of Trinidad. We document sustained net biomass accumulation and high rates of N fixation in these forests, regardless of the timing of selective timber harvests, including an old growth stand. The biomass accumulation was explained by growth of non-fixing trees, not N-fixing trees, but the total amount of symbiotic N fixation was sufficient to account for most of net above ground N demands, suggesting that N-fixers could contribute to the long-term C sink in these forests via fertilizing non-fixers.
- Published
- 2019