Forest response to increased disturbance in the central Amazon and comparison to western Amazonian forests

Uncertainties surrounding vegetation response to increased disturbance rates associated with climate change remains a major global change issue for Amazonian forests. Additionally, turnover rates computed as the average of mor- tality and recruitment rates in the western Amazon basin are doubled when compared to the central Amazon, and notable gradients currently exist in specific wood density and above- ground biomass (AGB) between these two regions. This study investigates the extent to which the variation in dis- turbance regimes contributes to these regional gradients. To address this issue, we evaluated disturbance-recovery pro- cesses in a central Amazonian forest under two scenarios of increased disturbance rates using first ZELIG-TROP, a dy- namic vegetation gap model which we calibrated using long- term inventory data, and second using the Community Land Model (CLM), a global land surface model that is part of the Community Earth System Model (CESM). Upon doubling the mortality rate in the central Amazon to mirror the natural disturbance regime in the western Amazon of 2 % mortal- ity, the two regions continued to differ in multiple forest pro- cesses. With the inclusion of elevated natural disturbances, at steady state, AGB significantly decreased by 41.9 % with no significant difference between modeled AGB and em- pirical AGB from the western Amazon data sets (104 vs. 107 Mg C ha 1 , respectively). However, different processes were responsible for the reductions in AGB between the models and empirical data set. The empirical data set sug- gests that a decrease in wood density is a driver leading to the reduction in AGB. While decreased stand basal area was the driver of AGB loss in ZELIG-TROP, a forest attribute that does not significantly vary across the Amazon Basin. Further comparisons found that stem density, specific wood density, and basal area growth rates differed between the two Amazo- nian regions. Last, to help quantify the impacts of increased disturbances on the climate and earth system, we evaluated the fidelity of tree mortality and disturbance in CLM. Similar to ZELIG-TROP, CLM predicted a net carbon loss of 49.9 %, with an insignificant effect on aboveground net primary pro- ductivity (ANPP). Decreased leaf area index (LAI) was the driver of AGB loss in CLM, another forest attribute that does not significantly vary across the Amazon Basin, and the tem- poral variability in carbon stock and fluxes was not replicated in CLM. Our results suggest that (1) the variability between regions cannot be entirely explained by the variability in dis- turbance regime, but rather potentially sensitive to intrinsic environmental factors; or (2) the models are not accurately simulating all tropical forest characteristics in response to in- creased disturbances.

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