Abstract
Forests are important for biodiversity, timber production and carbon accumulation, but these ecosystem services may be impacted by climate change. Field data collected from individual forest types occurring across a climatic gradient can contribute to forecasting these consequences. We examined how changes in temperature, precipitation and aridity affect ecosystem services in 23 mature Douglas-fir (Pseudotsuga menziesii) forests in nine climatic regions across a 900 km gradient in British Columbia, Canada. Using Canadian National Forest Inventory methodology, we assessed richness and diversity of plant functional groups, site index, and above- and below-ground carbon stocks. As aridity increased, ecosystem-level tree species richness declined on average from four to one species, Douglas-fir site index declined from 30 to 15 m, and ecosystem carbon storage decreased from 565 to 222 Mg ha–1. Tree species richness was positively and herb species richness negatively correlated with carbon storage. Carbon storage by ecosystem compartment was largest in aboveground live tree biomass, declining in the following order: mineral soils > coarse woody debris and dead standing trees > forest floor > small and fine woody debris > understory plants. Mineral soil carbon at depths of 0-15 cm, 15-35 cm, and 35-55 cm increased with increasing mean annual precipitation and decreasing aridity. Our results indicate that as aridity increases and precipitation decreases, tree species richness, site index and carbon storage in existing Douglas-fir forests declines. However, assisted or natural migration of Douglas-fir into more humid regions could be associated with more diverse, productive, carbon-rich forests. This study informs carbon stock vulnerability and provides empirical data essential for carbon stock forecasts.
Highlights
Douglas-fir (Pseudotsuga menziesii var. glauca (Beissn.) Franco) temperate forests in interior British Columbia, Canada are good candidates for conducting gradient studies to estimate how climate influences whole-ecosystem carbon (C) stocks as these forests are widely distributed across varied climatic regions and are predicted to be subject to and sensitive to climate change
The site index of species other than Douglas-fir followed the same trends as Douglas-fir (Supplementary Table I-1)
Our study investigated relationships between climatic factors and biodiversity, potential productivity as measured by site index, and C storage in the Douglasfir forest type in British Columbia
Summary
Douglas-fir (Pseudotsuga menziesii var. glauca (Beissn.) Franco) temperate forests in interior British Columbia, Canada are good candidates for conducting gradient studies to estimate how climate influences whole-ecosystem carbon (C) stocks as these forests are widely distributed across varied climatic regions and are predicted to be subject to and sensitive to climate change. Niche modeling based on predicted changes in temperature and precipitation has generated projections that Douglas-fir’s suitability range in British Columbia could expand substantially northward in the coming decades (projected expansion of 82 and 124% by 2055 and 2085, respectively; Hamann and Wang, 2006). Interior Douglas-fir is sensitive to limited soil water availability during the growing season (Littell et al, 2008; Chen et al, 2010; Griesbauer and Green, 2010; Griesbauer et al, 2011; Restaino et al, 2016) and drought is an important growth limiting factor for the species across all biogeoclimatic zones in British Columbia (Lloyd et al, 1990; Braumandl and Curran, 1992; Delong et al, 1993; Steen and Coupe, 1997; Coops et al, 2010). While the potential for future range expansion of Douglas-fir is promising, the consequences of changing aridity for existing forests requires further examination
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