Abstract
AbstractThe biogeochemical processes of carbon (C), nitrogen (N), and phosphorous (P) are fully coupled in the Earth system, which shape the structure, functioning, and dynamics of terrestrial ecosystems. However, the representation of P cycle in terrestrial biosphere models (TBMs) is still in an early stage. Here we incorporated P processes and C‐N‐P interactions into the C‐N coupled Dynamic Land Ecosystem Model (DLEM‐CNP), which had a major feature of the ability in simulating the N and P colimitation on vegetation C assimilation. DLEM‐CNP was intensively calibrated and validated against daily or annual observations from four eddy covariance flux sites, two Hawaiian sites along a chronosequence of soils, and other 13 tropical forest sites. The results indicate that DLEM‐CNP significantly improved simulations of forest gross and net primary production (R2: 0.36–0.97, RMSE:1.1–1.49 g C m−2 year−1 for daily GPP at eddy covariance flux sites; R2 = 0.92, RMSE = 176.7 g C m−2 year−1 for annual NPP across 13 tropical forest sites). The simulations were also consistent with field observations in terms of biomass, leaf N:P ratio and plant response to fertilizer addition. A sensitivity analysis suggests that simulated results are reasonably robust against uncertainties in model parameter estimates and the model was very sensitive to parameters of P uptake. These results suggest that incorporating P processes and N‐P interaction into terrestrial biosphere models is of critical importance for accurately estimating C dynamics in tropical forests, particularly those P‐limited ones.
Highlights
In many terrestrial ecosystems, the availability of soil nutrients shapes their structures and functions, including vegetation productivity, biodiversity, succession, and interactions of plant, animal, and microbial communities (Vitousek, 2004)
The results indicate that Dynamic Land Ecosystem Model (DLEM)‐CNP significantly improved simulations of forest gross and net primary production (R2: 0.36–0.97, root‐mean‐square error (RMSE):1.1–1.49 g C m−2 year−1 for daily GPP at eddy covariance flux sites; R2 = 0.92, RMSE = 176.7 g C m−2 year−1 for annual NPP across 13 tropical forest sites)
A sensitivity analysis suggests that simulated results are reasonably robust against uncertainties in model parameter estimates and the model was very sensitive to parameters of P uptake. These results suggest that incorporating P processes and N‐P interaction into terrestrial biosphere models is of critical importance for accurately estimating C dynamics in tropical forests, those P‐limited ones
Summary
The availability of soil nutrients shapes their structures and functions, including vegetation productivity, biodiversity, succession, and interactions of plant, animal, and microbial communities (Vitousek, 2004). P comes primarily from parent material weathering and atmospheric deposition and is lost through nutrient leaching, soil erosion, and fire (Filippelli, 2008; Newman, 1995; Wang et al, 2015). P limitation on primary productivity may intensify in the future as a result of rising atmospheric CO2 and nitrogen (N) deposition, which can weaken the carbon sequestration capability of terrestrial ecosystems (Goll et al, 2012; Zhang et al, 2014)
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