Abstract
Carbon release from thawing permafrost soils could significantly exacerbate global warming as the active‐layer deepens, exposing more carbon to decay. Plant community and soil properties provide a major control on this by influencing the maximum depth of thaw each summer (active‐layer thickness; ALT), but a quantitative understanding of the relative importance of plant and soil characteristics, and their interactions in determine ALTs, is currently lacking. To address this, we undertook an extensive survey of multiple vegetation and edaphic characteristics and ALTs across multiple plots in four field sites within boreal forest in the discontinuous permafrost zone (NWT, Canada). Our sites included mature black spruce, burned black spruce and paper birch, allowing us to determine vegetation and edaphic drivers that emerge as the most important and broadly applicable across these key vegetation and disturbance gradients, as well as providing insight into site‐specific differences. Across sites, the most important vegetation characteristics limiting thaw (shallower ALTs) were tree leaf area index (LAI), moss layer thickness and understory LAI in that order. Thicker soil organic layers also reduced ALTs, though were less influential than moss thickness. Surface moisture (0–6 cm) promoted increased ALTs, whereas deeper soil moisture (11–16 cm) acted to modify the impact of the vegetation, in particular increasing the importance of understory or tree canopy shading in reducing thaw. These direct and indirect effects of moisture indicate that future changes in precipitation and evapotranspiration may have large influences on ALTs. Our work also suggests that forest fires cause greater ALTs by simultaneously decreasing multiple ecosystem characteristics which otherwise protect permafrost. Given that vegetation and edaphic characteristics have such clear and large influences on ALTs, our data provide a key benchmark against which to evaluate process models used to predict future impacts of climate warming on permafrost degradation and subsequent feedback to climate.
Highlights
The mass of the permafrost carbon (C) stock is estimated to be almost twice that of the atmosphere, totalling ca. 1300 Pg (Hugelius et al, 2014)
active-layer thickness (ALT) were greatest at the Mosquito Spruce Burned (MSB) site, intermediate at Boundary Creek Birch (BB) and smallest at both Mosquito Spruce Unburned (MSU) and Boundary Creek Spruce (BS) (Fig. 2a, Table S1)
This study provides the most comprehensive assessment of how ALT varies with vegetation and soil characteristics in boreal forest, and is the first to separate data on moss, vascular vegetation and soil organic layer properties
Summary
The mass of the permafrost carbon (C) stock is estimated to be almost twice that of the atmosphere, totalling ca. 1300 Pg (Hugelius et al, 2014). As permafrost thaws an increasing amount of previously frozen C is exposed to microbial decomposition and can be transferred to the atmosphere and hydrosphere (Zimov et al, 2006; Schuur et al, 2009; Schaefer et al, 2011). This transfer is of major concern given that high latitudes are predicted to experience the fastest rate of warming compared to the rest of the globe (IPCC, 2013). As a result of the surface offset
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