Nina L. Friggens scite author profile

In arctic ecosystems, climate change has increased plant productivity. As arctic carbon (C) stocks predominantly are located belowground, the effects of greater plant productivity on soil C storage will significantly determine the net sink/source potential of these ecosystems, but vegetation controls on soil CO 2 efflux remain poorly resolved. In order to identify the role of canopy-forming species in belowground C dynamics, we conducted a girdling experiment with plots distributed across 1 km 2 of treeline birch (Betula pubescens) forest and willow (Salix lapponum) patches in northern Sweden and quantified the contribution of canopy vegetation to soil CO 2 fluxes and belowground productivity. Girdling birches reduced total soil CO 2 efflux in the peak growing season by 53%, which is double the expected amount, given that trees contribute only half of the total leaf area in the forest. Root and mycorrhizal mycelial production also decreased substantially. At peak season, willow shrubs contributed 38% to soil CO 2 efflux in their patches. Our findings indicate that C, recently fixed by trees and tall shrubs, makes a substantial contribution to soil respiration. It is critically important that these processes are taken into consideration in the context of a greening arctic because productivity and ecosystem C sequestration are not synonymous.

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Spatial patterns in soil organic matter dynamics are shaped by mycorrhizosphere interactions in a treeline forest

Friggens

Aspray

Parker

et al. 2019

Plant Soil

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Aims In the Swedish sub-Arctic, mountain birch (Betula pubescens ssp. czerepanovii) forests mediate rapid soil C cycling relative to adjacent tundra heaths, but little is known about the role of individual trees within forests. Here we investigate the spatial extent over which trees influence soil processes. Methods We measured respiration, soil C stocks, root and mycorrhizal productivity and fungi:bacteria ratios at fine spatial scales along 3 m transects extending radially from mountain birch trees in a sub-Arctic ecotone forest. Root and mycorrhizal productivity was quantified using in-growth techniques and fungi:bacteria ratios were determined by qPCR. Results Neither respiration, nor root and mycorrhizal production, varied along transects. Fungi:bacteria ratios, soil organic C stocks and standing litter declined with increasing distance from trees. Conclusions As 3 m is half the average size of forest gaps, these findings suggest that forest soil environments are efficiently explored by roots and associated mycorrhizal networks of B. pubescens. Individual trees exert influence substantially away from their base, creating more uniform distributions of root, mycorrhizal and bacterial activity than expected. However, overall rates of soil C accumulation do vary with distance from trees, with potential implications for spatio-temporal soil organic matter dynamics and net ecosystem C sequestration.

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Nina L. Friggens

Tree planting in organic soils does not result in net carbon sequestration on decadal timescales

Rhizosphere allocation by canopy‐forming species dominates soil CO₂ efflux in a subarctic landscape

Spatial patterns in soil organic matter dynamics are shaped by mycorrhizosphere interactions in a treeline forest

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Nina L. Friggens

Tree planting in organic soils does not result in net carbon sequestration on decadal timescales

Rhizosphere allocation by canopy‐forming species dominates soil CO2 efflux in a subarctic landscape

Spatial patterns in soil organic matter dynamics are shaped by mycorrhizosphere interactions in a treeline forest

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Rhizosphere allocation by canopy‐forming species dominates soil CO₂ efflux in a subarctic landscape