Methane cycling in a drained wetland soil profile

Purpose Peatlands have an important role in methane cycling in the natural environment. Methane emissions as a result of methanogenesis and methanotrophy in soil are affected by several environmental factors such as temperature, oxygen and groundwater level. The objective of this study was to analys...

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Bibliographic Details
Published in:Journal of soils and sediments 2017-07, Vol.17 (7), p.1874-1882
Main Authors: Jerman, Vesna, Danevčič, Tjaša, Mandic-Mulec, Ines
Format: Article
Language:English
Subjects:
Abundance
Area
Availability
Biogeochemistry
Communities
Cycles
Depth
Drainage
Earth and Environmental Science
Energy
Environment
Environmental factors
Environmental Physics
Exudates
Exudation
Fens
Flooded soils
Grasslands
Groundwater
Groundwater levels
Groundwater table
Incubation period
Iron
ISEB 2015: Biogeochemical Dynamics of Sediment-Water Systems: Processes and Modelling
Marshes
Methane
Methanogenesis
Methanotrophic bacteria
Methods
Mineralization
Natural environment
Organic matter
Organic soils
Oxidation
Oxygen
Peat
Peat soils
Peatlands
Reclamation
Sampling
Slurries
Soil
Soil depth
Soil investigations
Soil layers
Soil microorganisms
Soil organic matter
Soil profiles
Soil quality
Soil Science & Conservation
Soil temperature
Substrates
Temperature
Temperature effects
Water
Water table
Water table fluctuations
Wetlands
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Summary:Purpose Peatlands have an important role in methane cycling in the natural environment. Methane emissions as a result of methanogenesis and methanotrophy in soil are affected by several environmental factors such as temperature, oxygen and groundwater level. The objective of this study was to analyse methane cycling as a function of soil depth. Materials and methods In this study, methane cycling and soil organic matter mineralization were investigated in a drained fen grassland area of Ljubljana marsh, Slovenia that has been subjected to reclamation strategies for several centuries. Potential mineralization, methane production and methane oxidation rates were measured in slurry incubation experiments with soil samples from 10 sampling depths of a 1-m profile. In addition, the extent of iron reduction in the soil was determined. Results and discussion The potential for methane production was low in the investigated soil profile, even in constantly flooded layers below the water table fluctuations. During anaerobic incubations, the highest accumulated concentrations and production rates of methane were observed in the upper 10-cm layer and the lowest in deeper soil layers, indicating that plant exudates are the main source of energy for heterotrophic soil microbes and that methanogenesis in deeper layers is limited by the availability of appropriate organic substrates. Methane oxidation was on the other hand active throughout the soil profile, suggesting that the potentially active methane oxidizing community is present despite low methane production. The highest abundance and activity of methanotrophs was detected in the water table fluctuation layers. Conclusions Together, these findings have implications for understanding the biogeochemical function of drained peat soils and emphasize the influence of drainage on quality of soil organic matter and consequently on methane production even in flooded soils.
ISSN:1439-0108
1614-7480
DOI:10.1007/s11368-016-1648-2