Abstract
Lianas are structural parasites of trees that cause a reduction in tree growth and an increase in tree mortality. Thereby, lianas negatively impact forest carbon storage as evidenced by liana removal experiments. In this proof-of-concept study, we calibrated the Ecosystem Demography model (ED2) using 3 years of observations of net aboveground biomass (AGB) changes in control and removal plots of a liana removal experiment on Gigante Peninsula, Panama. After calibration, the model could accurately reproduce the observations of net biomass changes, the discrepancies between treatments, as well as the observed components of those changes (mortality, productivity, and growth). Simulations revealed that the long-term total (i.e., above- and belowground) carbon storage was enhanced in liana removal plots (+1.2 kgC m–2 after 3 years, +1.8 kgC m–2 after 10 years, as compared to the control plots). This difference was driven by a sharp increase in biomass of early successional trees and the slow decomposition of liana woody tissues in the removal plots. Moreover, liana removal significantly reduced the simulated heterotrophic respiration (−24%), which resulted in an average increase in net ecosystem productivity (NEP) from 0.009 to 0.075 kgC m–2 yr–1 for 10 years after liana removal. Based on the ED2 model outputs, lianas reduced gross and net primary productivity of trees by 40% and 53%, respectively, mainly through competition for light. Finally, model simulations suggested a profound impact of the liana removal on the soil carbon dynamics: the simulated metabolic litter carbon pool was systematically larger in control plots (+51% on average) as a result of higher mortality rates and faster leaf and root turnover rates. By overcoming the challenge of including lianas and depicting their effect on forest ecosystems, the calibrated version of the liana plant functional type (PFT) as incorporated in ED2 can predict the impact of liana removal at large-scale and its potential effect on long-term ecosystem carbon storage.
Highlights
Lianas are an important yet overlooked component of tropical forests (Schnitzer, 2018)
This study presents the proof of concept that ED2 and its liana plant functional type (PFT) can be calibrated against the field data of a removal experiment in order to (i) provide new insights into the mechanisms governing liana and tree competition, and (ii) extend the findings of such a liana removal experiment
Gigante Peninsula is located on a mainland peninsula within the Barro Colorado Nature Monument (BCNM) and supports a mix of early and late secondary seasonally moist lowland forest
Summary
Lianas (woody vines) are an important yet overlooked component of tropical forests (Schnitzer, 2018). As structural parasites, they climb tree stems to reach the forest canopy (Stevens, 1987) and in doing so, avoid massive carbon investment in self-supporting tissues (Ewers et al, 2015). They climb tree stems to reach the forest canopy (Stevens, 1987) and in doing so, avoid massive carbon investment in self-supporting tissues (Ewers et al, 2015) Lianas compete with their hosts for resources with an intensity that has been shown to be stronger than the regular tree-tree competition (Tobin et al, 2012). Experimental studies include CO2 enrichment (Norby and Zak, 2011), nutrient addition (Schnitzer et al, 2020), and liana removal experiments
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