Abstract
Research Highlights: Ongoing land-use change and climate change in wet tropical forests can potentially drive shifts in tree species composition, representing a change in individual species within a functional group, tropical evergreen trees. The impacts on the global carbon cycle are potentially large, but unclear. We explored the differential effects of species within this functional group, in comparison with the effects of climate change, using the Century model as a research tool. Simulating effects of individual tree species on biome-level biogeochemical cycles constituted a novel application for Century. Background and Objectives: A unique, long-term, replicated field experiment containing five evergreen tree species in monodominant stands under similar environmental conditions in a Costa Rican wet forest provided data for model evaluation. Our objectives were to gain insights about this forest’s biogeochemical cycles and effects of tree species within this functional group, in comparison with climate change. Materials and Methods: We calibrated Century, using long-term meteorological, soil, and plant data from the field-based experiment. In modeling experiments, we evaluated effects on forest biogeochemistry of eight plant traits that were both observed and modeled. Climate-change simulation experiments represented two climate-change aspects observed in this region. Results: Model calibration revealed that unmodeled soil processes would be required to sustain observed P budgets. In species-traits experiments, three separate plant traits (leaf death rate, leaf C:N, and allocation to fine roots) resulted in modeled biomass C stock changes of >50%, compared with a maximum 21% change in the climate-change experiments. Conclusions: Modeled ecosystem properties and processes in Century were sensitive to changes in plant traits and nutrient limitations to productivity. Realistic model output was attainable for some species, but unusual plant traits thwarted predictions for one species. Including more plant traits and soil processes could increase realism, but less-complex models provide an accessible means for exploring plant-soil-atmosphere interactions.
Highlights
Interactions between plants and soil are fundamental to terrestrial ecosystem processes, which are strongly influenced by changes in climate and land use [1]
In two separate sets of modeling experiments designed for the wet tropical forest biome, we evaluated the effects on ecosystem processes of: (1) two aspects of climate change that occur in evaluated the effects on ecosystem processes of: (1) two aspects of climate change that occur in this region and (2) eight tropical tree traits that have the potential to influence biogeochemical cycles
Balancing the C, N, and P budgets required additional nutrient inputs, suggesting that processes not currently contained in the model, such as erosion, sequential reduction and oxidation, and changes in soil pH play important roles in soil C and nutrient dynamics in tropical soils with variable-charge clays
Summary
Interactions between plants and soil are fundamental to terrestrial ecosystem processes, which are strongly influenced by changes in climate and land use [1]. These changes influence biological activity, which in turn alters C cycling, with feedbacks to climate change. Gross C emissions from tropical deforestation were reported to be 2.2 Pg C year−1 for the period 2000 to 2010 [4,5]. This loss represents a large potential for replacement of that forest
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