Abstract
Rising atmospheric [CO2 ] (Ca ) generally enhances tree growth if nutrients are not limiting. However, reduced water availability and elevated evaporative demand may offset such fertilization. Trees with access to deep soil water may be able to mitigate such stresses and respond more positively to Ca . Here, we sought to evaluate how increased vapor pressure deficit and reduced precipitation are likely to modify the impact of elevated Ca (eCa ) on tree productivity in an Australian Eucalyptus saligna Sm. plantation with access to deep soil water. We parameterized a forest growth simulation model (GOTILWA+) using data from two field experiments on E. saligna: a 2-year whole-tree chamber experiment with factorial Ca (ambient=380, elevated=620μmolmol-1 ) and watering treatments, and a 10-year stand-scale irrigation experiment. Model evaluation showed that GOTILWA+ can capture the responses of canopy C uptake to (1) rising vapor pressure deficit (D) under both Ca treatments; (2) alterations in tree water uptake from shallow and deep soil layers during soil dry-down; and (3) the impact of irrigation on tree growth. Simulations suggest that increasing Ca up to 700μmolmol-1 alone would result in a 33% increase in annual gross primary production (GPP) and a 62% increase in biomass over 10years. However, a combined 48% increase in D and a 20% reduction in precipitation would halve these values. Our simulations identify high D conditions as a key limiting factor for GPP. They also suggest that rising Ca will compensate for increasing aridity limitations in E. saligna trees with access to deep soil water under non-nutrient limiting conditions, thereby reducing the negative impacts of global warming upon this eucalypt species. Simulation models not accounting for water sources available to deep-rooting trees are likely to overestimate aridity impacts on forest productivity and C stocks.
Highlights
| MATERIAL AND METHODSA computerized irrigation system capable of supplying a uniform distribution of water across each plot at a rate of 7 mm h−1 was installed
We found that a 48% increase in D will limit the elevated Ca (eCa) fertilization effect on aboveground biomass stock (ABS) at a similar magnitude as a 20% reduction in precipitation
The positive responses projected in the Hawkesbury Forest Experiment (HFE) to combined eCa and increasing aridity are related to the ability of the eucalypts to access deep soil water reservoirs
Summary
A computerized irrigation system capable of supplying a uniform distribution of water across each plot at a rate of 7 mm h−1 was installed. To include drought limitations on photosynthesis (FvCB+β model), we ran a third inverse calibration with the same simulation setup This time, observations were taken from the An/Ci curves from the WTC dry-down experiment, and measured at 350 ≤ Ca ≤700 μmol mol−1 conditions (n = 137). For all least-squares regressions, homoscedasticity and normality of the residuals were visually checked, and data were log-transformed when necessary
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