Abstract
BackgroundUnderstanding how trees respond to drought is critical to forecasting both short and long-term impacts of climate change on forests. The isotopic ratio of 13C to 12C stored in wood – referred to as δ13C – is widely used as an indicator of plant water status. Yet whether changes in δ13C linked to drought are also associated with declines in annual carbon assimilation and allocation to stem growth remains unclear.MethodsHere we used tree ring data from over 3000 trees – representing 26 populations of 16 common European tree species sampled at six locations that span more than 20° in latitude – to test whether drought induces coordinated changes in carbon isotope ratios and stem basal area increments (BAI).ResultsWe found that δ13C is a reliable indicator of drought across a wide range of species and environmental conditions. All but one of the populations sampled in this study showed a statistically significant increase in δ13C under drought conditions. However, when considering the effects of these same drought events on BAI, we found no evidence to suggest that increases in δ13C were coupled with significant declines in stem growth. While BAI was 11.9% lower on average in drought years, this decline in BAI was not significant when analysed across species. In fact, only seven of the 26 populations we sampled exhibited significant declines in BAI under drought conditions – four of these from a single study site in the Carpathian Mountains of Romania.ConclusionsWhile δ13C responded strongly and consistently to drought across a diverse group of tree species and environmental conditions, we found that most tree species were able to sustain growth even under conditions of low soil water availability. Consequently, while δ13C provides a powerful indicator of past drought occurrence, by themselves carbon isotope ratios tell us little about how carbon sequestration and allocation to wood are affected by conditions of low water availability across Europe’s forests.
Highlights
Understanding how trees respond to drought is critical to forecasting both short and long-term impacts of climate change on forests
We found that broadleaves had significantly lower Ratio of 13C to 12C (δ13C) values compared to conifers (−27.10‰ compared to −26.18‰ in non-drought conditions, P = 0.003, and −26.20‰ compared to −25.03‰ in the drought year, P < 0.001)
The magnitude of the variation in δ13C between drought and non-drought years was similar in the two functional groups (Δδ13C = 0.90‰ and 1.15‰ respectively, P = 0.22)
Summary
Understanding how trees respond to drought is critical to forecasting both short and long-term impacts of climate change on forests. Whether changes in δ13C linked to drought are associated with declines in annual carbon assimilation and allocation to stem growth remains unclear. Δ13C reflects plant water status at the time of carbon fixation, and by analysing the isotopic composition of wood in tree rings we can reconstruct a picture of past drought events (Leavitt 1993; Warren et al 2001; Gessler et al 2014). Whether δ13C signals obtained from tree rings reflect rates of annual carbon assimilation and allocation to stem growth remains unclear (Ferrio et al 2003; Peñuelas et al 2008; Jansen et al 2013; Belmecheri et al 2014; Hentschel et al 2016; Shestakova et al 2017)
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