Abstract
Abstract. At the northernmost extent of the managed forest in Quebec, Canada, the boreal forest is currently undergoing an ecological transition between two forest ecosystems. Open lichen woodlands (LW) are spreading southward at the expense of more productive closed-canopy black spruce–moss forests (MF). The objective of this study was to investigate whether soil properties could distinguish MF from LW in the transition zone where both ecosystem types coexist. This study brings out clear evidence that differences in vegetation cover can lead to significant variations in soil physical and geochemical properties.Here, we showed that soil carbon, exchangeable cations, and iron and aluminium crystallinity vary between boreal closed-canopy forests and open lichen woodlands, likely attributed to variations in soil microclimatic conditions. All the soils studied were typical podzolic soil profiles evolved from glacial till deposits that shared a similar texture of the C layer. However, soil humus and the B layer varied in thickness and chemistry between the two forest ecosystems at the pedon scale. Multivariate analyses of variance were used to evaluate how soil properties could help distinguish the two types at the site scale. MF humus (FH horizons horizons composing the O layer) showed significantly higher concentrations of organic carbon and nitrogen and of the main exchangeable base cations (Ca, Mg) than LW soils. The B horizon of LW sites held higher concentrations of total Al and Fe oxides and particularly greater concentrations of inorganic amorphous Fe oxides than MF mineral soils, while showing a thinner B layer. Overall, our results show that MF store three times more organic carbon in their soils (B+FH horizons, roots apart) than LW. We suggest that variations in soil properties between MF and LW are linked to a cascade of events involving the impacts of natural disturbances such as wildfires on forest regeneration that determines the vegetation structure (stand density) and composition (ground cover type) and their subsequent consequences on soil environmental parameters (moisture, radiation rate, redox conditions, etc.). Our data underline significant differences in soil biogeochemistry under different forest ecosystems and reveal the importance of interactions in the soil–vegetation–climate system for the determination of soil composition.
Highlights
Vegetation–soil interactions are complex and constitutive processes of ecosystem dynamics, materialised by functional feedback roles between plant communities and the soil sys-Published by Copernicus Publications on behalf of the European Geosciences Union.C
moss forests (MF) are characterised by dense stands mainly composed of black spruce (Picea mariana) with a ground layer dominated by feather mosses (Pleurozium schreberi and others) and sphagnum (Sphagnum spp.)
We found that B : C ratios were different between mf and lw soils for many chemical properties
Summary
C. Bastianelli et al.: Boreal coniferous forest density leads to variations in soil properties tem (Richter and Yaalon, 2012; Van der Putten et al, 2013). The current ecosystem shift could be due to a change in the regional fire regime (Ali et al, 2012; Rapanoela et al, 2016) that likely occurred several thousands of years ago (Richard, 1979; Asselin and Payette, 2005) and constitutes a hot stake raised by forest ecologists and forest managers in so far as open black spruce–lichen woodlands are less productive and, sequester less carbon than closed moss forests (Rapanoela et al, 2016; Van Bogaert et al, 2015). In LW, black spruce stands as the dominant and quasi-exclusive tree species, yet tree density cover is a lot scarcer and the predominant ground cover vegetation is composed of lichens, mostly Cladonia spp
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
