Plant carbon allocation drives turnover of old soil organic matter in permafrost tundra soils

Carbon cycle feedbacks from permafrost ecosystems are expected to accelerate global climate change. Shifts in vegetation productivity and composition in permafrost regions could influence soil organic carbon (SOC) turnover rates via rhizosphere (root zone) priming effects (RPEs), but these processes...

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Bibliographic Details
Published in:Global Change Biology
Main Authors: Street, Lorna E, Garnett, Mark H, Subke, Jens-Arne, Wookey, Philip A, Baxter, Robert, Dean, Joshua F
Other Authors: NERC Natural Environment Research Council, University of Edinburgh, NERC Radiocarbon Facility (SUERC), Biological and Environmental Sciences, Durham University, University of Liverpool, orcid:0000-0001-9244-639X, orcid:0000-0001-5957-6424
Format: Article in Journal/Newspaper
Language:English
Published: Wiley 2020
Subjects:
radiocarbon
arctic
priming
root
rhizosphere
shrub
vegetation change
mycorrhiza
isotopes
belowground
Arctic
Climate change
permafrost
Tundra
Online Access:http://hdl.handle.net/1893/31227
https://doi.org/10.1111/gcb.15134
http://dspace.stir.ac.uk/bitstream/1893/31227/1/gcb.15134.pdf
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Summary:Carbon cycle feedbacks from permafrost ecosystems are expected to accelerate global climate change. Shifts in vegetation productivity and composition in permafrost regions could influence soil organic carbon (SOC) turnover rates via rhizosphere (root zone) priming effects (RPEs), but these processes are not currently accounted for in model predictions. We use a radiocarbon (bomb-14C) approach to test for RPEs in two Arctic tall shrubs,alder (Alnus viridis (Chaix) DC) and birch (Betula glandulosa Michx.)), and in ericaceous heath tundra vegetation. We compare surface CO2 efflux rates and 14C content between intact vegetation and plots in which belowground allocation of recent photosynthate was prevented by trenching and removal of aboveground biomass. We show, for the first time, that recent photosynthate drives mineralization of older (> 50 years old) SOC under birch shrubs and ericaceous heath tundra. By contrast, we find no evidence of RPEs in soils under alder. This is the first direct evidence from permafrost systems that vegetation influences SOC turnover through belowground C allocation. The vulnerability of SOC to decomposition in permafrost systems may therefore be directly linked to vegetation change, such that expansion of birch shrubs across the Arctic could increase decomposition of older SOC. Our results suggest that carbon cycle models that don’t include RPEs risk underestimating the carbon cycle feedbacks associated with changing conditions in tundra regions.

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