Abstract
The future trajectory of atmospheric CO2 concentration depends on the development of the terrestrial carbon sink, which in turn is influenced by forest dynamics under changing environmental conditions. An in-depth understanding of model sensitivities and uncertainties in non-steady-state conditions is necessary for reliable and robust projections of forest development and under scenarios of global warming and CO2 enrichment. Here, we systematically assessed if a biogeochemical process-based model (3D-CMCC-CNR), which embeds similarities with many other vegetation models, applied in simulating net primary productivity (NPP) and standing woody biomass (SWB), maintained a consistent sensitivity to its 55 input parameters through time, during forest ageing and structuring as well as under climate change scenarios. Overall, the model applied at three contrasting European forests showed low sensitivity to the majority of its parameters. Interestingly, model sensitivity to parameters varied through the course of >100 yr of simulations. In particular, the model showed a large responsiveness to the allometric parameters used for initialize forest carbon and nitrogen pools early in forest simulation (i.e., for NPP up to ~37%, 256 g C·m−2·yr−1 and for SWB up to ~90%, 65 Mg C/ha, when compared to standard simulation), with this sensitivity decreasing sharply during forest development. At medium to longer time scales, and under climate change scenarios, the model became increasingly more sensitive to additional and/or different parameters controlling biomass accumulation and autotrophic respiration (i.e., for NPP up to ~30%, 167 g C·m−2·yr−1 and for SWB up to ~24%, 64 Mg C/ha, when compared to standard simulation). Interestingly, model outputs were shown to be more sensitive to parameters and processes controlling stand development rather than to climate change (i.e., warming and changes in atmospheric CO2 concentration) itself although model sensitivities were generally higher under climate change scenarios. Our results suggest the need for sensitivity and uncertainty analyses that cover multiple temporal scales along forest developmental stages to better assess the potential of future forests to act as a global terrestrial carbon sink.
Original language | English |
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Article number | e01837 |
Journal | Ecological Applications |
Volume | 29 |
Issue number | 2 |
DOIs | |
State | Published - Mar 2019 |
Funding
We thank B. E. Medlyn, I. C. Prentice, M. G. Ryan, R. A. Fisher, H. Bugmann, C. Biondo and M. Bagnara, and B. Bond-Lamberty for many early useful comments and suggestions during model development and implementation and sensitivity analysis. We are also very thankful to an anonymous reviewer and to D. S. Schimel for constructive comments that significantly helped improving the manuscript. We also thank Principal Investigators at the sites for the data we used for this work. A. Collalti was supported by the European Union’s Horizon 2020 research and innovation program under grant agreement No. 641816 (CRESCENDO project; http://crescendoproject.eu/) and by the ALForLab (PON03PE_00024_1) project cofunded by the National Operational Program for Research and Competitiveness (PON R&C) 2007–2013, through the European Regional Development Fund (ERDF) and national resource (Revolving Fund—Cohesion Action Plan (PAC). P. E. Thornton’s participation in this research was supported as part of the Energy Exascale Earth System Model (E3SM) project, funded by the U.S. Department of Energy, Office of Science, Office of Biological and Environmental Research. C. Trotta was supported by the LIFE Project OLIVE4CLIMATE of the European Union under contract number LIFE15 CCM/IT/000141. We thank the ISIMIP project (Inter Sectoral Impact Model Intercomparison Project, https://www.isimip.org/) and the COST-Action PROFOUND (“Towards robust PROjections of European FOrests UNDer climate change”, FP 1304) for providing the scenarios used in this work. A. Collalti conceived the project, designed the experiments, developed the model code, performed the simulations, analyzed the data, and wrote the manuscript. P. E. Thornton, A. Collalti, C. Trotta, and G. Mat-teucci contributed in designing the experiment, co-developing the model code, and writing the manuscript. A. Rita, A. Nolè, P. Ciais, and M. Borgheti contributed in writing the manuscript.
Funders | Funder number |
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Cohesion Action Plan | |
National Operational Program for Research and Competitiveness | PON R&C |
U.S. Department of Energy | |
Office of Science | |
Biological and Environmental Research | |
Horizon 2020 Framework Programme | 641816, PON03PE_00024_1 |
European Commission | LIFE15 CCM/IT/000141 |
European Regional Development Fund |
Keywords
- autotrophic respiration
- climate change
- forest development
- forest structuring
- model sensitivity
- model uncertainty
- net primary productivity