The availability of nitrogen (N) and phosphorus (P) controls the flow of carbon (C) among plants, soils, and the atmosphere, thereby shaping terrestrial ecosystem responses to global change. Soil C, N, and P cycles are linked by drivers operating at multiple spatial and temporal scales: landscape-level variation in macroclimate and soil geochemistry, stand-scale heterogeneity in forest composition, and microbial community dynamics at the soil pore scale. Yet in many biomes, we do not know at which scales most of the biogeochemical variation emerges, nor which processes drive cross-scale feedbacks. Here, we examined the drivers and spatial/temporal scales of variation in soil biogeochemistry across four tropical dry forests spanning steep environmental gradients. To do so, we quantified soil C, N, and P pools, extracellular enzyme activities, and microbial community structure across wet and dry seasons in 16 plots located in Colombia, Costa Rica, Mexico, and Puerto Rico. Soil biogeochemistry exhibited marked heterogeneity across the 16 plots, with total organic C, N, and P pools varying fourfold, and inorganic nutrient pools by an order of magnitude. Most soil characteristics changed more across space (i.e., among sites and plots) than over time (between dry and wet season samplings). We observed stoichiometric decoupling among C, N, and P cycles, which may reflect their divergent biogeochemical drivers. Organic C and N pool sizes were positively correlated with the relative abundance of ectomycorrhizal trees and legumes. By contrast, the distribution of soil P pools was driven by soil geochemistry, with larger inorganic P pools in soils with P-rich parent material. Most earth system models assume that soils within a texture class operate similarly, and ignore subgrid cell variation in soil properties. Here we reveal that soil nutrient pools and fluxes exhibit as much variation among four Neotropical dry forests as is observed across terrestrial ecosystems at the global scale. Soil biogeochemical patterns are driven not only by regional differences in soil parent material and climate, but also by local-scale variation in plant and microbial communities. Thus, the biogeochemical patterns we observed across the Neotropical dry forest biome challenge representation of soil processes in ecosystem models.
Bibliographical noteFunding Information:
We thank the United States Department of Energy for funding through the research grant DE-SC0014363. We thank Daniel P?rez-Aviles, Ram?n Agosto Diaz, David Riverta-Polanco, and Tristan A.P. Allerton for help in the field and Sara Bauer and Jon Bertram for help in the lab. In Puerto Rico, we acknowledge P.G. Murphy and the International Institute of Tropical Forestry for initial site work and Eloy Mart?nez and Darien L?pez of the Puerto Rico Departamento de Recursos Naturales y Ambientales for site access. This work is Technical Contribution No. 6841 of the Clemson University Experiment Station.
We thank the United States Department of Energy for funding through the research grant DE‐SC0014363. We thank Daniel Pérez‐Aviles, Ramón Agosto Diaz, David Riverta‐Polanco, and Tristan A.P. Allerton for help in the field and Sara Bauer and Jon Bertram for help in the lab. In Puerto Rico, we acknowledge P.G. Murphy and the International Institute of Tropical Forestry for initial site work and Eloy Martínez and Darien López of the Puerto Rico Departamento de Recursos Naturales y Ambientales for site access. This work is Technical Contribution No. 6841 of the Clemson University Experiment Station.
© 2021 by the Ecological Society of America
- spatial scale
- tropical dry forest