Abstract
Globally increasing anthropogenic airborne emissions of reactive nitrogen (N) generate several environmental issues that require investigating how N accumulation modifies the N cycle. Tree-ring δ15N series may help understanding past and current perturbations in the forest N cycle. Although several studies have addressed this issue, most of them were of local scale or based on short δ15N series. The development of this environmental indicator however would benefit from examining, at the regional scale, the relationships of long tree-ring series with soil N biogeochemical processes. Here we explore these links for tree stands of the oil-sands region in northern Alberta, and the coal-fired power plants region in central Alberta, Canada. We characterize the tree-ring δ15N trends, the N modification rates and bacterial and fungal communities of soil samples collected in the immediate surrounding of the characterized trees. The dataset suggests that specific soil pH, and N-cycling bacterial and fungal communities influence tree-ring δ15N responses to anthropogenic emissions, correlating either directly or inversely. Overall, tree-ring δ15N series may record changes in the forest-N cycle, but their interpretation requires understanding key soil biogeochemical processes. «In nature nothing exists alone», Rachel Carson.
Highlights
Anthropogenic emissions of reactive N in the atmosphere have more than doubled globally since the beginning of industrialization, generating several health concerns, climatic impacts and environmental issues [1]
This research focuses on the coal-fired power plant (CFPP) region, southwest of Edmonton, known to generate the highest NOx emissions in Canada, and the surface mining oil sands (OS) region of the Lower Athabasca, north of Fort McMurray in northern Alberta
Rootlets collected in four directions around trees were separated manually from rootlet prats coated with ectomycorrhizal fungi (EcM)
Summary
Anthropogenic emissions of reactive N in the atmosphere have more than doubled globally since the beginning of industrialization, generating several health concerns, climatic impacts and environmental issues [1]. With the main incentives of separating natural effects from anthropogenic perturbations and attempting to provide a retrospective look at the forest N cycle in these two regions, Natural Resources Canada and collaborators conducted several multidisciplinary research activities to characterize air, soil, fungi, lakes and trees in exposed forests [2,3,4,5]. This proceeding combines isotopic geochemistry, dendrochronology, with soil biogeochemistry, genomics and microbial ecology, and briefly discusses the post-depositional processes modifying the biogeochemical pathways in soils and trees
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