Abstract
Stable carbon isotope ratios (δ13C) in tree rings have been widely used to study changes in intrinsic water-use efficiency (iWUE), sometimes with limited consideration of how C-isotope discrimination is affected by tree height and canopy position. Our goals were to quantify the relationships between tree size or tree microenvironment and wood δ13C for eight functionally diverse temperate tree species in northern New England and to better understand the physical and physiological mechanisms underlying these differences. We collected short increment cores in closed-canopy stands and analyzed δ13C in the most recent 5years of growth. We also sampled saplings in both shaded and sun-exposed environments. In closed-canopy stands, we found strong tree-size effects on δ13C, with 3.7-7.2‰ of difference explained by linear regression vs height (0.11-0.28‰ m-1), which in some cases is substantially stronger than the effect reported in previous studies. However, open-grown saplings were often isotopically more similar to large codominant trees than to shade-grown saplings, indicating that light exposure contributes more to the physiological and isotopic differences between small and large trees than does height. We found that in closed-canopy forests, δ13C correlations with diameter at breast height were nonlinear but also strong, allowing a straightforward procedure to correct tree- or stand-scale δ13C-based iWUE chronologies for changing tree size. We demonstrate how to use such data to correct and interpret multi-decadal composite isotope chronologies in both shade-regenerated and open-grown tree cohorts, and we highlight the importance of understanding site history when interpreting δ13C time series.
Highlights
Stable carbon isotope ratios (δ13C; Coplen 2011) in tree rings have been widely used to estimate intrinsic water use efficiency, defined as the ratio of photosynthesis to stomatal conductance (McCarroll and Loader 2004)
The dominant driver of isotopic differences seen in our sampled trees (Figs 2,4a)
Cannot be separated from the light effect using our data. This effect is overridden by the sum of the others
Summary
Stable carbon isotope ratios (δ13C; Coplen 2011) in tree rings (or any plant tissue; δ13Cp) have been widely used to estimate intrinsic water use efficiency (iWUE), defined as the ratio of photosynthesis to stomatal conductance (McCarroll and Loader 2004) These measurements are potentially of great importance for physiologists interested in how the fundamental balance between transpiration and photosynthesis may be shifting due to a variety of global change factors, ranging from changes in climate (Lévesque et al 2014, Zhang et al 2018) to acid deposition (Thomas et al 2013). Tree-ring studies of iWUE have sometimes been undertaken without correcting for the potential isotopic effects of tree growth, though often a tree’s earliest years of growth are excluded from analysis, due to well-documented “juvenile effects” This term refers to factors which depress iWUE in young trees relative to canopy trees due to differences between canopy and sub-canopy conditions, as well as increasing hydraulic resistance with height. Failure to account for such effects could lead to a misattribution of age-driven iWUE trends to drivers such as CO2 or climate
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