Assessing the long‐term carbon‐sequestration potential of the semi‐natural salt marshes in the European Wadden Sea

Mueller, Peter; Ladiges, Nils; Jack, Alexander; Schmiedl, Gerhard; Kutzbach, Lars; Jensen, Kai

doi:10.1002/ecs2.2556

Cited by 53 publications

(50 citation statements)

References 50 publications

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“…In our site, silt and clay contents represent approx. 80% of the deposited mineral matter and their contributions do not vary across the elevation gradient within the marsh (Butzeck et al, ; Mueller et al, ). In accordance with this, slopes and y ‐intercepts of the relationships between EEA per unit dry weight and organic/mineral content are relatively consistent across zones, indicating similarly active mineral‐associated enzyme pools (Figure a).…”

Section: Discussionmentioning

confidence: 99%

Unrecognized controls on microbial functioning in Blue Carbon ecosystems: The role of mineral enzyme stabilization and allochthonous substrate supply

Mueller

Granse

Nolte

et al. 2020

Ecology and Evolution

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Tidal wetlands are effective carbon sinks, mitigating climate change through the long-term removal of atmospheric CO 2 . Studies along surface-elevation and thus flooding-frequency gradients in tidal wetlands are often used to understand the effects of accelerated sea-level rise on carbon sequestration, a process that is primarily determined by the balance of primary production and microbial decomposition. It

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Section: Discussionmentioning

confidence: 99%

Unrecognized controls on microbial functioning in Blue Carbon ecosystems: The role of mineral enzyme stabilization and allochthonous substrate supply

Mueller

Granse

Nolte

et al. 2020

Ecology and Evolution

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“…Soils in both sites have OM contents <15% and are dominated by grain-sizes <63 µm (>70% silts and clays) (Mueller et al 2019). Flooding of the extensive high-marsh platforms, that this study is restricted to, only occurs during storm events predominantly in winter (Müller et al 2013a, Butzeck et al 2015.…”

Section: Study Sites and Sampling Designmentioning

confidence: 95%

Origin of organic carbon in the topsoil of Wadden Sea salt marshes

Mueller¹,

Thi²,

Jensen³

et al. 2019

Mar. Ecol. Prog. Ser.

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Blue carbon ecosystems, including salt marshes, play an important role in the global carbon cycle because of their high efficiency to store soil organic carbon (OC). Few studies focus on the origin of OC stored in salt-marsh soils, which comes from either allochthonous or autochthonous sources. The origin, however, has important implications for carbon crediting approaches because the alternative fate of allochthonous OC (AllOC), i.e. if it had not accumulated in the Blue C ecosystem, is unclear. Here, we assessed the origin of OC in two mainland salt-marsh sites of the European Wadden Sea, analyzing δ 13 C of topsoil (0-5 cm) samples, freshly deposited sediment (allochthonous source), and of above-and belowground biomass of vegetation (autochthonous sources). We tested for effects of geomorphological factors, including elevation and the distance to sediment sources, and of livestock grazing, as the most important land-use form, on the relative contributions of allochthonous versus autochthonous sources to the topsoil OC stock. A negative effect of distance to the creek on the relative contribution of AllOC was found at only one of the two salt marshes, probably 2 due to differences in micro-topography between the two salt marshes. Additionally, the relative contribution of AllOC increased with increasing distance to the marsh edge in areas without livestock-grazing, while it decreased in grazed areas. Our findings demonstrate that spatial factors such as surface elevation and distance to a sediment source, which have been found to determine the spatial patterns of sediment deposition, also are important factors determining the relative contribution of AllOC to topsoil OC stocks of salt marshes. Furthermore, we provide first evidence that livestock-grazing can reduce the relative contribution of AllOC to the soil OC stock. These findings thereby yield important implications for C crediting and land-use management.

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“…Environmental context determines much of the external carbon inputs to salt marshes. For instance, sedimentation rates are linked to the local tidal regime (Stumpf, 1983) and allochthonous organic matter, that imported with marine sediment rather than created on the salt marsh, can contribute considerably to SOC stocks where tall vegetation traps sediment (Van de Broek et al, 2018;Mueller et al, 2019). Arguably, the impact of grazing on saltmarsh carbon is comparatively weak relative to the influence of sharp background environmental gradients (Grime, 1974;Nolte et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

“…Salt marshes, along with mangroves and seagrass beds, are thought to provide longer-lasting and far denser "blue" carbon stores than most terrestrial systems, although salt marsh carbon stocks do vary considerably with marsh maturity, geomorphology and environmental setting (Sousa et al, 2010;Mcleud et al, 2011;Hayes et al, 2017;Himes-Cornell et al, 2018). Carbon stores are rich and long-lasting in marshes because they have high plant productivity (Middelburg et al, 1997) and sulfate rich, anaerobic sediments with slow organic deposition rates (Howarth, 1984;Valiela et al, 1985;Mueller et al, 2017) The low-energy, depositional characteristics of salt marshes also make them excellent carbon sinks (Chmura et al, 2003;Andersen et al, 2010) as much of the particulate material trapped by marshes is rich in externally produced organic matter (Van de Broek et al, 2018;Mueller et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

No Detectable Broad-Scale Effect of Livestock Grazing on Soil Blue-Carbon Stock in Salt Marshes

et al. 2019

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Grassland carbon capturing and storage (CCS) is thought to benefit from regulation of grazing. The impact is likely to depend on livestock density. Yet, few studies have tested this principle or evaluated the consistency of grazer-carbon relationships across multiple sites. We sampled four intertidal zones across 22 salt marshes along a 650 km stretch of coast in the UK to examine the impact of livestock density on globally important saltmarsh "blue carbon" stocks. Although there were marked impacts of grazing pressure on above ground vegetation composition, structure and biomass, there was no detectable relationship between grazing intensity and soil organic carbon, irrespective of tidal zone in the marsh or soil depth-layer analyzed. A substantial spatial variation in soil carbon was instead explained by contextual environmental variables. There was evidence that compensatory responses by vegetation, such as increased root growth, countered carbon loss from grazing impacts. Our work suggests that grazing effects on carbon stocks are minimal on broader scales in comparison with the influence of environmental context. The benefits of grazing management to carbon stores are likely to be highly context dependent.

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Assessing the long‐term carbon‐sequestration potential of the semi‐natural salt marshes in the European Wadden Sea

Cited by 53 publications

References 50 publications

Unrecognized controls on microbial functioning in Blue Carbon ecosystems: The role of mineral enzyme stabilization and allochthonous substrate supply

Unrecognized controls on microbial functioning in Blue Carbon ecosystems: The role of mineral enzyme stabilization and allochthonous substrate supply

Origin of organic carbon in the topsoil of Wadden Sea salt marshes

No Detectable Broad-Scale Effect of Livestock Grazing on Soil Blue-Carbon Stock in Salt Marshes

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