Linking rhizospheric CH4 oxidation and net CH4 emissions in an arctic wetland based on 13CH4 labeling of mesocosms

Cecilie Skov Nielsen; Anders Michelsen; Per Ambus; T. K. K. Chamindu Deepagoda; Bo Elberling

doi:10.1007/s11104-016-3061-4

Linking rhizospheric CH₄ oxidation and net CH₄ emissions in an arctic wetland based on ¹³CH₄ labeling of mesocosms

Cecilie Skov Nielsen, Anders Michelsen, Per Ambus, T. K. K. Chamindu Deepagoda, Bo Elberling^*

^*Corresponding author for this work

9 Citations (Scopus)

Abstract

Aims: Poorly drained arctic ecosystems are potential large emitters of methane (CH₄) due to their high soil organic carbon content and low oxygen availability. In wetlands, aerenchymatous plants transport CH₄ from the soil to the atmosphere, but concurrently transport O₂ to the rhizosphere, which may lead to oxidation of CH₄. The importance of the latter process is largely unknown for arctic plant species and ecosystems. Here, we aim to quantify the subsurface oxidation of CH₄ in a waterlogged arctic ecosystem dominated by Carex aquatilis ssp. stans and Eriophorum angustifolium, and evaluate the overall effect of these plants on the CH₄ budget. Methods: A mesocosms study was established based on the upper 20 cm of an organic soil profile with intact plants retrieved from a peatland in West Greenland (69°N). We measured dissolved concentrations and emissions of ¹³CO₂ and ¹³CH₄ from mesocosms during three weeks after addition of ¹³C-enriched CH₄ below the mesocosm. Results: Most of the recovered ¹³C label (>98 %) escaped the ecosystem as CH₄, while less than 2 % was oxidized to ¹³CO₂. Conclusions: It is concluded that aerenchymatous plants control the overall CH₄ emissions but, as a transport system for oxygen, are too inefficient to markedly reduce CH₄ emissions.

Original language	English
Journal	Plant and Soil
Volume	412
Issue number	1-2
Pages (from-to)	201–213
Number of pages	13
ISSN	0032-079X
DOIs	https://doi.org/10.1007/s11104-016-3061-4
Publication status	Published - 1 Mar 2017

Keywords

Carex
Greenhouse gases
Methane
Oxidation
Stable isotopes
Tundra

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10.1007/s11104-016-3061-4

Cite this

@article{ea5df5b38c1b4e919c7c3b2874b47689,

title = "Linking rhizospheric CH4 oxidation and net CH4 emissions in an arctic wetland based on 13CH4 labeling of mesocosms",

abstract = "Aims: Poorly drained arctic ecosystems are potential large emitters of methane (CH4) due to their high soil organic carbon content and low oxygen availability. In wetlands, aerenchymatous plants transport CH4 from the soil to the atmosphere, but concurrently transport O2 to the rhizosphere, which may lead to oxidation of CH4. The importance of the latter process is largely unknown for arctic plant species and ecosystems. Here, we aim to quantify the subsurface oxidation of CH4 in a waterlogged arctic ecosystem dominated by Carex aquatilis ssp. stans and Eriophorum angustifolium, and evaluate the overall effect of these plants on the CH4 budget. Methods: A mesocosms study was established based on the upper 20 cm of an organic soil profile with intact plants retrieved from a peatland in West Greenland (69°N). We measured dissolved concentrations and emissions of 13CO2 and 13CH4 from mesocosms during three weeks after addition of 13C-enriched CH4 below the mesocosm. Results: Most of the recovered 13C label (>98 %) escaped the ecosystem as CH4, while less than 2 % was oxidized to 13CO2. Conclusions: It is concluded that aerenchymatous plants control the overall CH4 emissions but, as a transport system for oxygen, are too inefficient to markedly reduce CH4 emissions.",

keywords = "Carex, Greenhouse gases, Methane, Oxidation, Stable isotopes, Tundra",

author = "Nielsen, {Cecilie Skov} and Anders Michelsen and Per Ambus and Deepagoda, {T. K. K. Chamindu} and Bo Elberling",

note = "CENPERM[2016]",

year = "2017",

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doi = "10.1007/s11104-016-3061-4",

language = "English",

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T1 - Linking rhizospheric CH4 oxidation and net CH4 emissions in an arctic wetland based on 13CH4 labeling of mesocosms

AU - Nielsen, Cecilie Skov

AU - Michelsen, Anders

AU - Ambus, Per

AU - Deepagoda, T. K. K. Chamindu

AU - Elberling, Bo

N1 - CENPERM[2016]

PY - 2017/3/1

Y1 - 2017/3/1

N2 - Aims: Poorly drained arctic ecosystems are potential large emitters of methane (CH4) due to their high soil organic carbon content and low oxygen availability. In wetlands, aerenchymatous plants transport CH4 from the soil to the atmosphere, but concurrently transport O2 to the rhizosphere, which may lead to oxidation of CH4. The importance of the latter process is largely unknown for arctic plant species and ecosystems. Here, we aim to quantify the subsurface oxidation of CH4 in a waterlogged arctic ecosystem dominated by Carex aquatilis ssp. stans and Eriophorum angustifolium, and evaluate the overall effect of these plants on the CH4 budget. Methods: A mesocosms study was established based on the upper 20 cm of an organic soil profile with intact plants retrieved from a peatland in West Greenland (69°N). We measured dissolved concentrations and emissions of 13CO2 and 13CH4 from mesocosms during three weeks after addition of 13C-enriched CH4 below the mesocosm. Results: Most of the recovered 13C label (>98 %) escaped the ecosystem as CH4, while less than 2 % was oxidized to 13CO2. Conclusions: It is concluded that aerenchymatous plants control the overall CH4 emissions but, as a transport system for oxygen, are too inefficient to markedly reduce CH4 emissions.

AB - Aims: Poorly drained arctic ecosystems are potential large emitters of methane (CH4) due to their high soil organic carbon content and low oxygen availability. In wetlands, aerenchymatous plants transport CH4 from the soil to the atmosphere, but concurrently transport O2 to the rhizosphere, which may lead to oxidation of CH4. The importance of the latter process is largely unknown for arctic plant species and ecosystems. Here, we aim to quantify the subsurface oxidation of CH4 in a waterlogged arctic ecosystem dominated by Carex aquatilis ssp. stans and Eriophorum angustifolium, and evaluate the overall effect of these plants on the CH4 budget. Methods: A mesocosms study was established based on the upper 20 cm of an organic soil profile with intact plants retrieved from a peatland in West Greenland (69°N). We measured dissolved concentrations and emissions of 13CO2 and 13CH4 from mesocosms during three weeks after addition of 13C-enriched CH4 below the mesocosm. Results: Most of the recovered 13C label (>98 %) escaped the ecosystem as CH4, while less than 2 % was oxidized to 13CO2. Conclusions: It is concluded that aerenchymatous plants control the overall CH4 emissions but, as a transport system for oxygen, are too inefficient to markedly reduce CH4 emissions.

KW - Carex

KW - Greenhouse gases

KW - Methane

KW - Oxidation

KW - Stable isotopes

KW - Tundra

U2 - 10.1007/s11104-016-3061-4

DO - 10.1007/s11104-016-3061-4

M3 - Journal article

AN - SCOPUS:84988734891

SN - 0032-079X

VL - 412

SP - 201

EP - 213

JO - Plant and Soil

JF - Plant and Soil

IS - 1-2

ER -