Experimentally increased nutrient availability at the permafrost thaw front selectively enhances biomass production of deep-rooting subarctic peatland species

International audience Climate warming increases nitrogen (N) mineralization in superficial soil layers (the dominant rooting zone) of subarctic peatlands. Thawing and subsequent mineralization of permafrost increases plant-available N around the thaw-front. Because plant production in these peatlan...

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Bibliographic Details
Published in:Global Change Biology
Main Authors: Keuper, Frida, Dorrepaal, Ellen, van Bodegom, Peter M., van Logtestijn, Richard, Venhuizen, Gemma, van Hal, Jurgen, Aerts, Rien
Other Authors: Agroressources et Impacts environnementaux (AgroImpact), Institut National de la Recherche Agronomique (INRA), Vrije Universiteit Amsterdam Amsterdam (VU), UmeƄ University, Leiden University, Darwin Centre for Biogeosciences 142.161.042, FP6 506004, EU-ATANS 142.161.042, FP6 506004
Format: Article in Journal/Newspaper
Language:English
Published: HAL CCSD 2017
Subjects:
belowground nitrogen
climate change
Empetrum hermaphroditum
fertilization
frozen soil
permafrost thaw
root uptake
Rubus chamaemorus
[SDV]Life Sciences [q-bio]
[SDV.BV]Life Sciences [q-bio]/Vegetal Biology
[SDE]Environmental Sciences
permafrost
Subarctic
Online Access:https://hal.inrae.fr/hal-02619005
https://doi.org/10.1111/gcb.13804
Description
Summary:International audience Climate warming increases nitrogen (N) mineralization in superficial soil layers (the dominant rooting zone) of subarctic peatlands. Thawing and subsequent mineralization of permafrost increases plant-available N around the thaw-front. Because plant production in these peatlands is N-limited, such changes may substantially affect net primary production and species composition. We aimed to identify the potential impact of increased N-availability due to permafrost thawing on subarctic peatland plant production and species performance, relative to the impact of increased N-availability in superficial organic layers. Therefore, we investigated whether plant roots are present at the thaw-front (45 cm depth) and whether N-uptake (N-15-tracer) at the thaw-front occurs during maximum thaw-depth, coinciding with the end of the growing season. Moreover, we performed a unique 3-year belowground fertilization experiment with fully factorial combinations of deep-(thaw-front) and shallow-fertilization (10 cm depth) and controls. We found that certain species are present with roots at the thaw-front (Rubus chamaemorus) and have the capacity (R. chamaemorus, Eriophorum vaginatum) for N-uptake from the thaw-front between autumn and spring when aboveground tissue is largely senescent. In response to 3-year shallow-belowground fertilization (S) both shallow-(Empetrum hermaphroditum) and deep-rooting species increased aboveground biomass and N-content, but only deep-rooting species responded positively to enhanced nutrient supply at the thaw-front (D). Moreover, the effects of shallow-fertilization and thaw-front fertilization on aboveground biomass production of the deep-rooting species were similar in magnitude (S: 71%; D: 111% increase compared to control) and additive (S + D: 181% increase). Our results show that plant-available N released from thawing permafrost can form a thus far overlooked additional N-source for deep-rooting subarctic plant species and increase their biomass production beyond the ...

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