Abstract
Climate change will impact forest productivity worldwide. Forecasting the magnitude of such impact, with multiple environmental stressors changing simultaneously, is only possible with the help of process-based models. In order to assess their performance, such models require careful evaluation against measurements. However, direct comparison of model outputs against observational data is often not reliable, as models may provide the right answers due to the wrong reasons. This would severely hinder forecasting abilities under unprecedented climate conditions. Here, we present a methodology for model assessment, which supplements the traditional output-to-observation model validation. It evaluates model performance through its ability to reproduce observed seasonal changes of the most limiting environmental driver (MLED) for a given process, here daily gross primary productivity (GPP). We analyzed seasonal changes of the MLED for GPP in two contrasting pine forests, the Mediterranean Pinus halepensis Mill. Yatir (Israel) and the boreal Pinus sylvestris L. Hyytiälä (Finland) from three years of eddy-covariance flux data. Then, we simulated the same period with a state-of-the-art process-based simulation model (LandscapeDNDC). Finally, we assessed if the model was able to reproduce both GPP observations and MLED seasonality. We found that the model reproduced the seasonality of GPP in both stands, but it was slightly overestimated without site-specific fine-tuning. Interestingly, although LandscapeDNDC properly captured the main MLED in Hyytiälä (temperature) and in Yatir (soil water availability), it failed to reproduce high-temperature and high-vapor pressure limitations of GPP in Yatir during spring and summer. We deduced that the most likely reason for this divergence is an incomplete description of stomatal behavior. In summary, this study validates the MLED approach as a model evaluation tool, and opens up new possibilities for model improvement.
Highlights
Temperature, water availability, and irradiation are key drivers of forest productivity
We focused on the daily limitation strength of four key environmental drivers on gross primary productivity (GPP), i.e., air temperature, incoming radiation, soil water availability, and vapor pressure deficit
At Yatir, GPPobs peaked during winter, while in Hyytiala, GPPobs peaked during summer, the growing season for high-latitudes in the Northern Hemisphere
Summary
Temperature, water availability, and irradiation are key drivers of forest productivity. In semiarid regions forest productivity is mostly limited by water availability Specific stressors occur that may directly affect tree functioning (e.g., ozone damage, herbivory grazing, pest occurrence), or swiftly increase water demand, as is the case of high atmospheric vapor pressure deficit (D). This leads to physiological adjustments, e.g., reduction of stomatal conductance, modifying the water transport in the soil–plant–atmosphere continuum and limiting leaf internal CO2 supply for photosynthesis (e.g., Novick et al 2016, Zhang et al 2019, Grossiord et al 2020)
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