Ancient fires enhance Amazon forest drought resistance

dc.contributor.authorVedovato Laura B., Carvalho Lidiany C. S., Aragao Luiz E. O. C., Bird Michael, Phillips Oliver L., Alvarez Patricia, Barlow Jos, Bartholomew David C., Berenguer Erika, Castro Wendeson, Ferreira Joice, Franca Filipe M., Malhi Yadvinder, Marimon Beatriz, Marimon Junior Ben Hur, Monteagudo Abel, Oliveira Edmar A., Pereira Luciana O., Pontes-Lopes Aline, Quesada Carlos A., Silva Camila V. J., Espejo Javier Silva E., Silveira Marcos, Feldpausch Ted R.
dc.date.accessioned2024-11-28T20:53:47Z
dc.date.available2024-11-28T20:53:47Z
dc.date.issuedMaynard Daniel S.
dc.description.abstractDrought and fire reduce productivity and increase tree mortality in tropical forests. Fires also produce pyrogenic carbon (PyC), which persists in situ for centuries to millennia, and represents a legacy of past fires, potentially improving soil fertility and water holding capacity and selecting for the survival and recruitment of certain tree life-history (or successional) strategies. We investigated whether PyC is correlated with physicochemical soil properties, wood density, aboveground carbon (AGC) dynamics and forest resistance to severe drought. To achieve our aim, we used an Amazon-wide, long-term plot network, in forests without known recent fires, integrating site-specific measures of forest dynamics, soil properties and a unique soil PyC concentration database. We found that forests with higher concentrations of soil PyC had both higher soil fertility and lower wood density. Soil PyC was not associated with AGC dynamics in non-drought years. However, during extreme drought events (10% driest years), forests with higher concentrations of soil PyC experienced lower reductions in AGC gains (woody growth and recruitment), with this drought-immunizing effect increasing with drought severity. Forests with a legacy of ancient fires are therefore more likely to continue to grow and recruit under increased drought severity. Forests with high soil PyC concentrations (third quartile) had 3.8% greater AGC gains under mean drought, but 33.7% greater under the most extreme drought than forests with low soil PyC concentrations (first quartile), offsetting losses of up to 0.68 Mg C ha(-1)yr(-1) of AGC under extreme drought events. This suggests that ancient fires have legacy effects on current forest dynamics, by altering soil fertility and favoring tree species capable of continued growth and recruitment during droughts. Therefore, mature forest that experienced fires centuries or millennia ago may have greater resistance to current short-term droughts.
dc.identifier.doiHart Simon P.
dc.identifier.issn,2023/02/14,http://dx.doi.org/10.3389/ffgc.2023.1024101 Hordijk Iris
dc.identifier.urihttps://publicacionesabiertas.userena.cl/handle/123456789/176
dc.languageEnglish
dc.publisherFRONTIERS MEDIA SA
dc.subjectBLACK CARBON, TROPICAL FOREST, SUSTAINABLE AGRICULTURE, PHYSICAL-PROPERTIES, TREE MORTALITY, CLIMATE-CHANGE,WOOD DENSITY, SOIL, DEFORESTATION, INCREASES
dc.titleAncient fires enhance Amazon forest drought resistance
dc.typeArticle

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