Above‐ to belowground carbon allocation in peatlands shifts with plant functional type and temperature

Background Northern peatlands have accumulated vast amounts of carbon (C) as peat. Warming temperatures may affect peatland C stores by increasing microbial decomposition of ancient peat through enhanced input of labile root exudates by expansion of vascular plants, thereby accelerating atmospheric...

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Published in:Journal of plant nutrition and soil science 2022-02, Vol.185 (1), p.98-109
Main Authors: Zeh, Lilli, Schmidt‐Cotta, Claudia, Limpens, Juul, Bragazza, Luca, Kalbitz, Karsten
Format: Article
Language:English
Subjects:
13C
Carbon
Carbon dioxide
climate change
Depletion
Exudates
Exudation
Flowers & plants
Labeling
Microorganisms
Peat
Peat soils
peatland
Peatlands
Plant removal
Plants
pulse labelling
Respiration
sedges
Shoots
Shrubs
Soil temperature
Soils
Temperature
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Summary:Background Northern peatlands have accumulated vast amounts of carbon (C) as peat. Warming temperatures may affect peatland C stores by increasing microbial decomposition of ancient peat through enhanced input of labile root exudates by expansion of vascular plants, thereby accelerating atmospheric warming. Aims We set out to explore how much freshly assimilated C is allocated belowground by vascular plants, and if the above‐ to belowground allocation is affected by temperature and plant functional types. Methods We traced the C allocation pathways of two dominant plant functional types (i.e., sedges and shrubs) in two peatlands under different temperature regimes by combining selective plant removal in mixed sedge‐shrub vegetation and in situ 13C pulse‐labelling. Aboveground to belowground C allocation as well as the C turnover were assessed by quantifying 13C in plant leaves and soil respiration and by measuring δ13C in dissolved organic C. A depth‐resolved quantification of 13C in the peat soil gave additional insight into belowground C allocation patterns. Results Temperature did not affect the rate at which 13C was assimilated into shoots, but higher temperature decreased the fraction of assimilated C that was allocated belowground by vascular plants. Sedges assimilated CO2 faster into their shoot biomass (faster depletion in 13C in shoots) and allocated more of the assimilated 13C belowground than shrubs. Conversely, sedges retained this belowground allocated C better than shrubs, leading to lower 13C in soil respiration measured under sedges. Conclusions Climate induced vascular plant expansion will increase input of fresh assimilates into the peat substantially, even though part of this effect will be offset by reduced above‐ to belowground allocation rates. If shrub density increases relative to sedges, fresh assimilates are more likely to be respired than translocated to roots where they could reach and, potentially mobilize, ancient C stored in deeper peat layers.
ISSN:1436-8730
1522-2624
DOI:10.1002/jpln.202100206