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- Title
Disentangling seasonal and interannual legacies from inferred patterns of forest water and carbon cycling using tree‐ring stable isotopes.
- Authors
Szejner, Paul; Wright, William E.; Belmecheri, Soumaya; Meko, David; Leavitt, Steven W.; Ehleringer, James R.; Monson, Russell K.
- Abstract
Tree‐ring carbon and oxygen isotope ratios have been used to understand past dynamics in forest carbon and water cycling. Recently, this has been possible for different parts of single growing seasons by isolating anatomical sections within individual annual rings. Uncertainties in this approach are associated with correlated climate legacies that can occur at a higher frequency, such as across successive seasons, or a lower frequency, such as across years. The objective of this study was to gain insight into how legacies affect cross‐correlation in the δ13C and δ18O isotope ratios in the earlywood (EW) and latewood (LW) fractions of Pinus ponderosa trees at thirteen sites across a latitudinal gradient influenced by the North American Monsoon (NAM) climate system. We observed that δ13C from EW and LW has significant positive cross‐correlations at most sites, whereas EW and LW δ18O values were cross‐correlated at about half the sites. Using combined statistical and mechanistic models, we show that cross‐correlations in both δ13C and δ18O can be largely explained by a low‐frequency (multiple‐year) mode that may be associated with long‐term climate change. We isolated, and statistically removed, the low‐frequency correlation, which resulted in greater geographical differentiation of the EW and LW isotope signals. The remaining higher‐frequency (seasonal) cross‐correlations between EW and LW isotope ratios were explored using a mechanistic isotope fractionation–climate model. This showed that lower atmospheric vapor pressure deficits associated with monsoon rain increase the EW‐LW differentiation for both δ13C and δ18O at southern sites, compared to northern sites. Our results support the hypothesis that dominantly unimodal precipitation regimes, such as near the northern boundary of the NAM, are more likely to foster cross‐correlations in the isotope signals of EW and LW, potentially due to greater sharing of common carbohydrate and soil water resource pools, compared to southerly sites with bimodal precipitation regimes. The increasing use of intra‐annual isotope ratios in tree rings to reconstruct seasonal forest–climate interactions can propagate uncertainties associated with correlated climate effects across seasons and years. We show that variation in climate across gradients in a major climate system causes intraseasonal lag effects. If these lags are not considered, they could lead to biased interpretations of past and future patterns of forest–climate interactions. This can be useful to those interested in the influences of past spatiotemporal climate change on the water‐use efficiency of semi‐arid montane forest ecosystems.
- Subjects
CARBON cycle; TREE-rings; OXYGEN isotopes; CARBON isotopes; CLIMATE change; PALEOCLIMATOLOGY; METEOROLOGICAL precipitation
- Publication
Global Change Biology, 2018, Vol 24, Issue 11, p5332
- ISSN
1354-1013
- Publication type
Article
- DOI
10.1111/gcb.14395