Water level, vegetation composition, and plant productivity explain greenhouse gas fluxes in temperate cutover fens after inundation

Minke, Merten; Augustin, Jürgen; Burlo, A.; Yarmashuk, T.; Chuvashova, H.; Thiele, Annett; Freibauer, Annette; Tikhonov, V.; Hoffmann, Mathias

doi:10.5194/bg-13-3945-2016

Cited by 41 publications

(26 citation statements)

References 73 publications

(101 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A combination of wetland plant cover and high water level, but also non-inundation and high soil temperature, enhanced CH 4 emissions. This is in line with other studies for rewetted fens (e.g., [41]), shallow lakes [81], and rewetted peat extraction sites [45]. The higher CH 4 fluxes observed with increasing temperature for the Carex spp.-Typha latifolia community were associated with a steep slope in the linear mixed model function (Figure 3a,b).…”

Section: The Model Outcome: Influence Of Water Level Vegetation Commsupporting

confidence: 91%

“…Those tendencies are in line with the general understanding of N 2 O emergence in soils, where soil moisture is a major driver of N 2 O emissions [33,94]. Concerning the order of magnitude of the N2O emission fluxes from the non-inundated shore of the littoral zone, their overall level is not higher than on nutrient-rich temperate extracted fens after inundation [41] or from a cultivated fen peat [95]. All fluxes from the open water were below detection limit.…”

Section: N 2 O Fluxessupporting

confidence: 83%

“…Further, the transition from extracted peatland to wetland ecosystem may reduce the overall climate warming impact due to C sequestration (peat). Graminoids such as Calamagrostis canescens, Poa trivialis, and Concerning the order of magnitude of the N 2 O emission fluxes from the non-inundated shore of the littoral zone, their overall level is not higher than on nutrient-rich temperate extracted fens after inundation [41] or from a cultivated fen peat [95]. All fluxes from the open water were below detection limit.…”

Section: Discussionmentioning

confidence: 91%

See 2 more Smart Citations

Methane and Nitrous Oxide Emission Fluxes Along Water Level Gradients in Littoral Zones of Constructed Surface Water Bodies in a Rewetted Extracted Peatland in Sweden

et al. 2020

View full text Add to dashboard Cite

Rewetted extracted peatlands are sensitive ecosystems and they can act as greenhouse gas (GHG) sinks or sources due to changes in hydrology, vegetation, and weather conditions. However, studies on GHG emissions from extracted peatlands after rewetting are limited. Methane (CH4) and nitrous oxide (N2O) emission fluxes were determined using the opaque closed chamber method along water level gradients from littoral zones to the open water body of constructed shallow lakes with different vegetation zones in a nutrient-rich rewetted extracted peatland in Sweden. Vegetation communities and their position relative to water level, together with short-term water level fluctuations, such as inundation events and seasonal droughts, and temperature had a significant impact on CH4 emissions fluxes. During “normal” and “dry” conditions and high soil temperatures, CH4 emissions were highest from Carex spp.-Typha latifolia L. communities. During inundation events with water levels > 30 cm, sites with flooded Graminoids-Scirpus spp.-Carex spp. emitted most CH4. Methane emissions from the water body of the constructed shallow lakes were low during all water level conditions and over the temperature ranges observed. Nitrous oxide emissions contributed little to the emission fluxes from the soil-plant-water systems to the atmosphere, and they were only detectable from the sites with Graminoids. In terms of management, the construction of shallow lakes showed great potential for lowering GHG emission fluxes from nutrient rich peatlands after peat extraction, even though the vegetated shore emitted some N2O and CH4.

show abstract

Section: The Model Outcome: Influence Of Water Level Vegetation Commsupporting

confidence: 91%

Section: N 2 O Fluxessupporting

confidence: 83%

Section: Discussionmentioning

confidence: 91%

See 1 more Smart Citation

Methane and Nitrous Oxide Emission Fluxes Along Water Level Gradients in Littoral Zones of Constructed Surface Water Bodies in a Rewetted Extracted Peatland in Sweden

et al. 2020

View full text Add to dashboard Cite

show abstract

“…, ; Mettrop, Rutte, Kooijman, & Lamers, ; Minke et al . , ; Richert, Dietrich, Koppisch, & Roth, ). Different target water levels depending on the development goals of the sites are one of the main reasons why shallow water table sites are often the centre of conflicts between different interest groups, especially between farmers and nature protection groups.…”

Section: Introductionmentioning

confidence: 99%

“…A model study by Grimaldi, Orellana, and Daly (2015) emphasized that different plants with different root depths have various effects on evapotranspiration, create different drops in the water table and groundwater depletion, which is additionally affected by varying soil types. The restoration of former agriculturally utilized areas by rewetting, especially, leads to a change in the plant communities and has to be considered in the development of water management strategies Minke et al, 2016;Richert et al, 2000;Zak et al, 2015;Zerbe et al, 2013).…”

mentioning

confidence: 99%

Impact of groundwater regimes on water balance components of a site with a shallow water table

Dietrich

Kaiser

2017

Ecohydrology

View full text Add to dashboard Cite

The management of shallow water table sites is often the subject of discussion between different interest groups, the most controversial topic being the different target groundwater levels. A good level of knowledge about the effects of the different water levels on the water budget components is a precondition for the development of compromises in well‐balanced water resource management. We used groundwater lysimeters to investigate the impact of different water level regimes on the water balance. The lysimeters were installed directly within a typical shallow water table site and had a specially designed system to control the lower boundary condition. This enabled us to simulate different management options in a realistic way. Our results show increasing evapotranspiration with higher water levels but only if the vegetation is adapted to these conditions. Adaptation may take place within a few years of higher water levels. High water levels in spring are linked to increased water storage. This can help to compensate for the higher evapotranspiration for some weeks but not for the entire season. The meteorological conditions have a large short‐term impact on the water budget, which is difficult to compensate for using long‐term water management strategies or slow‐responding vegetation development. Our results underline the complex ecohydrological dependencies in such site conditions and could be an important basis for the development or improvement of ecohydrological models.

show abstract

Saving soil carbon, greenhouse gas emissions, biodiversity and the economy: paludiculture as sustainable land use option in German fen peatlands

2022

View full text Add to dashboard Cite

Peatlands in the European Union are largely drained for agriculture and emit 25% of the total agricultural greenhouse gas emissions. Drainage-based peatland use has also negative impacts on water quality, drinking water provision and biodiversity. Consequently, key EU environmental policy objectives include the rewetting of all drained peatlands as an essential nature-based solution. Rewetting of peatlands can be combined with site-adapted land use, so-called paludiculture. Paludiculture produces biomass from wet and rewetted peatlands under conditions that maintain the peat body, facilitate peat accumulation and can provide many of the ecosystem services associated with natural, undrained peatlands. The biomass can be used for a wide range of traditional and innovative food, feed, fibre and fuel products. Based on examples in Germany, we have analysed emerging paludiculture options for temperate Europe with respect to greenhouse gas fluxes, biodiversity and indicative business economics. Best estimates of site emission factors vary between 0 and 8 t CO2eq ha−1 y−1. Suitability maps for four peatland-rich federal states (76% of total German peatland area) indicate that most of the drained, agriculturally used peatland area could be used for paludiculture, about one-third of the fen area for any paludiculture type. Fen-specific biodiversity benefits from rewetting and paludiculture, if compared to the drained state. Under favourable conditions, paludiculture can be economically viable, but costs and revenues vary considerably. Key recommendations for large-scale implementation are providing planning security by paludiculture spatial planning, establishing best practice sites and strengthening research into crops, water tables and management options.

show abstract

Water level, vegetation composition, and plant productivity explain greenhouse gas fluxes in temperate cutover fens after inundation

Cited by 41 publications

References 73 publications

Methane and Nitrous Oxide Emission Fluxes Along Water Level Gradients in Littoral Zones of Constructed Surface Water Bodies in a Rewetted Extracted Peatland in Sweden

Methane and Nitrous Oxide Emission Fluxes Along Water Level Gradients in Littoral Zones of Constructed Surface Water Bodies in a Rewetted Extracted Peatland in Sweden

Impact of groundwater regimes on water balance components of a site with a shallow water table

Saving soil carbon, greenhouse gas emissions, biodiversity and the economy: paludiculture as sustainable land use option in German fen peatlands

Contact Info

Product

Resources

About