Environmental and microbial factors influencing methane and nitrous oxide fluxes in Mediterranean cork oak woodlands: trees make a difference

Shvaleva, Alla; Siljanen, Henri; Correia, Alexandra; Silva, Filipe Costa e; Lamprecht, Richard E.; Lobo‐do‐Vale, Raquel; Bicho, Catarina; Fangueiro, David; Anderson, Margaret; Pereira, J. S.; Chaves, M. M.; Cruz, Cristina; Martikainen, Pertti J.

doi:10.3389/fmicb.2015.01104

Cited by 18 publications

(11 citation statements)

References 73 publications

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“…Considering the entire un-stratified plot, spatial variability (evaluated as coefficient of variation CV) of the standardized CO2 and CH4 fluxes and non-standardized N2O flux was highest for N2O and similar for CO2 and CH4 (Tab. 1) and agrees well with data from literature [14,49]. Since the vegetation strata could explain some of the spatial variability of the soil gas fluxes at our site, our stratification approach reduced the CV for CH4 substantially, from 38% to 24% (Tab.…”

Section: Spatial Variability Of Soil Gas Fluxessupporting

confidence: 90%

“…Few studies though could stratify or explain spatial variability of GHG fluxes on the plot scale. Shvaleva et al [49] showed that tree cover had an effect on net N 2 O fluxes and that CH 4 fluxes were affected by soil organic carbon content. Darenova et al [14] identified litter thickness and local soil moisture as important factors affecting CO 2 fluxes on the plots scale within a forest and grassland.…”

Section: Spatial Variability Of Soil Gas Fluxesmentioning

confidence: 99%

“…Studies comparing plots of different vegetation could show that tree species can affect CH 4 consumptions by soils [25,26,49,53,54]. Menyailo et al [26] observed that tree species had an effect on methanotrophic activity in an afforestation, but that the composition of high affinity methantrophs was not altered.…”

Section: Spatial Variability Of Soil Gas Fluxesmentioning

confidence: 99%

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Drivers of Plot-Scale Variability of CH4 Consumption in a Well-Aerated Pine Forest Soil

Maier

Paulus

Nicolai

et al. 2017

Forests

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While differences in greenhouse gas (GHG) fluxes between ecosystems can be explained to a certain degree, variability of the same at the plot scale is still challenging. We investigated the spatial variability in soil-atmosphere fluxes of carbon dioxide (CO 2 ), methane (CH 4 ) and nitrous oxide (N 2 O) to find out what drives spatial variability on the plot scale. Measurements were carried out in a Scots pine (Pinus sylvestris L.) forest in a former floodplain on a 250 m 2 plot, divided in homogenous strata of vegetation and soil texture. Soil gas fluxes were measured consecutively at 60 points along transects to cover the spatial variability. One permanent chamber was measured repeatedly to monitor temporal changes to soil gas fluxes. The observed patterns at this control chamber were used to standardize the gas fluxes to disentangle temporal variability from the spatial variability of measured GHG fluxes. Concurrent measurements of soil gas diffusivity allowed deriving in situ methanotrophic activity from the CH 4 flux measurements. The soil emitted CO 2 and consumed CH 4 and N 2 O. Significantly different fluxes of CH 4 and CO 2 were found for the different soil-vegetation strata, but not for N 2 O. Soil CH 4 consumption increased with soil gas diffusivity within similar strata supporting the hypothesis that CH 4 consumption by soils is limited by the supply with atmospheric CH 4 . Methane consumption in the vegetation strata with dominant silty texture was higher at a given soil gas diffusivity than in the strata with sandy texture. The same pattern was observed for methanotrophic activity, indicating better habitats for methantrophs in silt. Methane consumption increased with soil respiration in all strata. Similarly, methanotrophic activity increased with soil respiration when the individual measurement locations were categorized into silt and sand based on the dominant soil texture, irrespective of the vegetation stratum. Thus, we suggest the rhizosphere and decomposing organic litter might represent or facilitate a preferred habitat for methanotrophic microbes, since rhizosphere and decomposing organic are the source of most of the soil respiration.

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Section: Spatial Variability Of Soil Gas Fluxessupporting

confidence: 90%

Section: Spatial Variability Of Soil Gas Fluxesmentioning

confidence: 99%

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Drivers of Plot-Scale Variability of CH4 Consumption in a Well-Aerated Pine Forest Soil

Maier

Paulus

Nicolai

et al. 2017

Forests

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“…Similarly, montado systems have a higher density and richness of ectomycorrhizal (ECM) fungal communities than regions with denser tree and shrub cover, due to lower competition; this can increase the resilience of the managed system due to improved nutrient acquisition, drought tolerance and pathogen resistance (Azul et al, 2010). The montado landscape has also been shown to have other effects such as lowering land surface temperature (Godinho et al, 2016) or affecting soil microbiology (Shvaleva et al, 2015) and soil fauna (Martins da Silva et al, 2015).…”

Section: Rewilding In Sloveniamentioning

confidence: 99%

The superior effect of nature based solutions in land management for enhancing ecosystem services

Keesstra

Nunes

Novara

et al. 2018

Science of The Total Environment

748

336

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The rehabilitation and restoration of land is a key strategy to recover services -goods and resources- ecosystems offer to the humankind. This paper reviews key examples to understand the superior effect of nature based solutions to enhance the sustainability of catchment systems by promoting desirable soil and landscape functions. The use of concepts such as connectivity and the theory of system thinking framework allowed to review coastal and river management as a guide to evaluate other strategies to achieve sustainability. In land management NBSs are not mainstream management. Through a set of case studies: organic farming in Spain; rewilding in Slovenia; land restoration in Iceland, sediment trapping in Ethiopia and wetland construction in Sweden, we show the potential of Nature based solutions (NBSs) as a cost-effective long term solution for hydrological risks and land degradation. NBSs can be divided into two main groups of strategies: soil solutions and landscape solutions. Soil solutions aim to enhance the soil health and soil functions through which local eco-system services will be maintained or restored. Landscape solutions mainly focus on the concept of connectivity. Making the landscape less connected, facilitating less rainfall to be transformed into runoff and therefore reducing flood risk, increasing soil moisture and reducing droughts and soil erosion we can achieve the sustainability. The enhanced eco-system services directly feed into the realization of the Sustainable Development Goals of the United Nations.

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“…Upland forest soils, even when well-aerated, can also act as a sink for atmospheric N 2 O. Periodic N 2 O uptake has been observed during dry periods in temperate Norway spruce forests (Bowden et al 1991;Klemedtsson et al 1997;Butterbach-Bahl et al 1998;Goldberg and Gebauer 2009), during spring and autumn in temperate Red pine (Bowden et al 1990) and Scots pine forests (Butterbach-Bahl et al 2002) and boreal pine dominated forest (Machakova et al 2019), in deciduous forests (Dong et al 1998;Goossens et al 2001), as well as in Mediterranean pine (Rosenkranz et al 2006) and oak forests (Shvaleva et al 2015). According to the best of our knowledge, data on N 2 O uptake from boreal spruce forests, an important coniferous forest type in the boreal region, is currently lacking.…”

Section: Introductionmentioning

confidence: 99%

Atmospheric impact of nitrous oxide uptake by boreal forest soils can be comparable to that of methane uptake

et al. 2020

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Aims Environmental factors controlling nitrous oxide (N2O) uptake in forest soils are poorly known, and the atmospheric impact of the forest N2O sink is not well constrained compared to that of methane (CH4). Methods We compared nitrous oxide (N2O) and CH4 fluxes over two growing seasons in boreal forest soils located in Eastern Finland. Within a spruce forest, we compared plots with long-term nitrogen (N) fertilization history and non-fertilized plots, and additionally pine forest plots without a fertilization history. The flux data was complemented with measurements of climatic conditions and soil physical and chemical characteristics, in order to identify factors affecting N2O and CH4 fluxes. Results Non-fertilized spruce forest soils showed the highest cumulative N2O uptake among the sites, whereas the pine forest site displayed low cumulative N2O emission. Nitrous oxide uptake was favored by high soil silt and water content. The low temperature seasons, spring and autumn, had the highest N2O uptake, likely associated with high soil water content typical for these seasons. In the spruce forest the N2O uptake was seasonally decoupled from the CH4 uptake. Conclusions Applying the Global Warming Potential (GWP) approach, the cooling effect of N2O uptake in the spruce forest was on average 35% of that of CH4 uptake showing that N2O uptake should be considered when evaluating the atmospheric impact of boreal forests.

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Environmental and microbial factors influencing methane and nitrous oxide fluxes in Mediterranean cork oak woodlands: trees make a difference

Cited by 18 publications

References 73 publications

Drivers of Plot-Scale Variability of CH4 Consumption in a Well-Aerated Pine Forest Soil

Drivers of Plot-Scale Variability of CH4 Consumption in a Well-Aerated Pine Forest Soil

The superior effect of nature based solutions in land management for enhancing ecosystem services

Atmospheric impact of nitrous oxide uptake by boreal forest soils can be comparable to that of methane uptake

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