A decade of free-air CO2 enrichment increased the carbon throughput in a grass-clover ecosystem but did not drastically change carbon allocation patterns

Philip L. Staddon; Sabine Reinsch; Pal A. Olsson; Per Lennart Ambus; Andreas Luescher; Iver Jakobsen

doi:10.1111/1365-2435.12183

A decade of free-air CO2 enrichment increased the carbon throughput in a grass-clover ecosystem but did not drastically change carbon allocation patterns

Philip L. Staddon, Sabine Reinsch, Pal A. Olsson, Per Lennart Ambus, Andreas Luescher, Iver Jakobsen

13 Citations (Scopus)

Abstract

The response of the soil carbon cycle to increasing atmospheric CO₂ concentration has far reaching consequences for the ecosystem carbon balance under future climatic conditions. We report on work carried out in the Swiss free-air CO₂ enrichment (FACE) experiment, where we used in situ ¹³CO₂ labelling to determine whether elevated CO₂ (+230 μL L^-1) concentration changes the fate of recently assimilated carbon in the soil microbial community. Elevated CO₂ (eCO₂) concentration had an overall positive effect on microbial abundance (P < 0·001) with the gram-negative bacteria showing significantly increased quantities. Gram-negative bacteria and saprotrophic fungi tended to utilize a higher amount of recently assimilated carbon under eCO₂. Arbuscular mycorrhizal fungi (AMF) utilized plant-assimilated carbon within 1 day after the ¹³CO₂ pulse and ¹³C uptake patterns in AMF suggest that carbon transfer is faster under eCO₂ concentration than under ambient CO₂ (aCO₂). Additionally, the respiration of recently assimilated carbon was significantly higher under eCO₂ than aCO₂ concentration. Our data suggest that elevated atmospheric CO₂ concentration accelerated and increased the utilization of recently assimilated carbon by the microbial community without changing the microbial community composition drastically. We conclude that a higher standing soil microbial biomass under eCO₂ concentration was the key cause for the higher carbon flow through the plant-soil system. Carbon utilization by microbial functional groups was only little affected by a decade of CO₂ enrichment.

Original language	English
Journal	Functional Ecology
Volume	28
Issue number	2, SI
Pages (from-to)	538-545
Number of pages	8
ISSN	0269-8463
DOIs	https://doi.org/10.1111/1365-2435.12183
Publication status	Published - 1 Apr 2014
Externally published	Yes

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A decade of free-air CO2 enrichment increased the carbon throughput in a grass-clover ecosystem but did not drastically change carbon allocation patterns. / Staddon, Philip L.; Reinsch, Sabine; Olsson, Pal A. et al.

In: Functional Ecology, Vol. 28, No. 2, SI, 01.04.2014, p. 538-545.

Research output: Contribution to journal › Journal article › Research › peer-review

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abstract = "The response of the soil carbon cycle to increasing atmospheric CO2 concentration has far reaching consequences for the ecosystem carbon balance under future climatic conditions. We report on work carried out in the Swiss free-air CO2 enrichment (FACE) experiment, where we used in situ 13CO2 labelling to determine whether elevated CO2 (+230 μL L-1) concentration changes the fate of recently assimilated carbon in the soil microbial community. Elevated CO2 (eCO2) concentration had an overall positive effect on microbial abundance (P < 0·001) with the gram-negative bacteria showing significantly increased quantities. Gram-negative bacteria and saprotrophic fungi tended to utilize a higher amount of recently assimilated carbon under eCO2. Arbuscular mycorrhizal fungi (AMF) utilized plant-assimilated carbon within 1 day after the 13CO2 pulse and 13C uptake patterns in AMF suggest that carbon transfer is faster under eCO2 concentration than under ambient CO2 (aCO2). Additionally, the respiration of recently assimilated carbon was significantly higher under eCO2 than aCO2 concentration. Our data suggest that elevated atmospheric CO2 concentration accelerated and increased the utilization of recently assimilated carbon by the microbial community without changing the microbial community composition drastically. We conclude that a higher standing soil microbial biomass under eCO2 concentration was the key cause for the higher carbon flow through the plant-soil system. Carbon utilization by microbial functional groups was only little affected by a decade of CO2 enrichment.",

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AB - The response of the soil carbon cycle to increasing atmospheric CO2 concentration has far reaching consequences for the ecosystem carbon balance under future climatic conditions. We report on work carried out in the Swiss free-air CO2 enrichment (FACE) experiment, where we used in situ 13CO2 labelling to determine whether elevated CO2 (+230 μL L-1) concentration changes the fate of recently assimilated carbon in the soil microbial community. Elevated CO2 (eCO2) concentration had an overall positive effect on microbial abundance (P < 0·001) with the gram-negative bacteria showing significantly increased quantities. Gram-negative bacteria and saprotrophic fungi tended to utilize a higher amount of recently assimilated carbon under eCO2. Arbuscular mycorrhizal fungi (AMF) utilized plant-assimilated carbon within 1 day after the 13CO2 pulse and 13C uptake patterns in AMF suggest that carbon transfer is faster under eCO2 concentration than under ambient CO2 (aCO2). Additionally, the respiration of recently assimilated carbon was significantly higher under eCO2 than aCO2 concentration. Our data suggest that elevated atmospheric CO2 concentration accelerated and increased the utilization of recently assimilated carbon by the microbial community without changing the microbial community composition drastically. We conclude that a higher standing soil microbial biomass under eCO2 concentration was the key cause for the higher carbon flow through the plant-soil system. Carbon utilization by microbial functional groups was only little affected by a decade of CO2 enrichment.

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A decade of free-air CO2 enrichment increased the carbon throughput in a grass-clover ecosystem but did not drastically change carbon allocation patterns

Abstract

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