High emissions of greenhouse gases from grasslands on peat and other organic soils

Tiemeyer, Bärbel; Borraz, Elisa Albiac; Augustin, Jürgen; Bechtold, Michel; Beetz, Sascha; Beyer, Colja; Drösler, Matthias; Ebli, Martin; Eickenscheidt, Tim; Fiedler, Sabine; Förster, Christoph; Freibauer, Annette; Giebels, Michael; Glatzel, Stephan; Heinichen, Jan; Hoffmann, Mathias; Höper, Heinrich; Jurasinski, Gerald; Leiber-Sauheitl, Katharina; Peichl-Brak, Mandy; Roßkopf, Niko; Sommer, Michael; Zeitz, Jutta

doi:10.1111/gcb.13303

Cited by 178 publications

(185 citation statements)

References 53 publications

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“…With rates of 6.5-9.4 t C ha −1 a −1 net CO 2 fluxes from organic soils now used as croplands were on average found to be higher than from organic soils under grassland, which were estimated to vary between 1.8 and 7.3 t C ha −1 a −1 (IPCC, 2014). However, recent studies reported emission rates of 7.6 ± 2.0 t C ha −1 a −1 on organic soils managed as grassland in Germany and thus much higher rates than previously found for this type of land use (Tiemeyer et al, 2016). Drained organic soils under forest can act as both net sinks or sources of atmospheric CO 2 (Cannell et al, 1993;Minkkinen and Laine, 1998;Minkkinen et al, 1999;Wüst-Galley et al, 2016), although they are in general considered to represent a source with average net CO 2 emissions of 2.0-3.3 t C ha −1 a −1 in the temperate zone (IPCC, 2014).…”

Section: Introductionmentioning

confidence: 60%

“…Although they cover only 3 % of the earth's terrestrial surface (Tubiello et al, 2016), they store up to 30 % of the global soil organic carbon (SOC) pool (Parish et al, 2008). In Europe, more than 50 % of the former peatland area has been degraded by peat mining and conversion of land use, including drainage, to improve their suitability for agriculture or forestry (Joosten, 2010).…”

Section: Introductionmentioning

confidence: 99%

“…This transforms the former C-sink into a major source of atmospheric carbon dioxide (CO 2 ) and makes peatlands an important contributor to global climate change (Freeman et al, 2004). Around 85 % of the global annual CO 2 emission of 915 Mt CO 2 -C from drained peatlands are estimated to originate from organic soils now used as croplands (Tubiello et al, 2016). With rates of 6.5-9.4 t C ha −1 a −1 net CO 2 fluxes from organic soils now used as croplands were on average found to be higher than from organic soils under grassland, which were estimated to vary between 1.8 and 7.3 t C ha −1 a −1 (IPCC, 2014).…”

Section: Introductionmentioning

confidence: 99%

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Peat decomposability in managed organic soils in relation to land use, organic matter composition and temperature

et al. 2018

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Abstract. Organic soils comprise a large yet fragile carbon (C) store in the global C cycle. Drainage, necessary for agriculture and forestry, triggers rapid decomposition of soil organic matter (SOM), typically increasing in the order forest < grassland < cropland. However, there is also large variation in decomposition due to differences in hydrological conditions, climate and specific management. Here we studied the role of SOM composition on peat decomposability in a variety of differently managed drained organic soils. We collected a total of 560 samples from 21 organic cropland, grassland and forest soils in Switzerland, monitored their CO 2 emission rates in lab incubation experiments over 6 months at two temperatures (10 and 20 • C) and related them to various soil characteristics, including bulk density, pH, soil organic carbon (SOC) content and elemental ratios (C / N, H / C and O / C). CO 2 release ranged from 6 to 195 mg CO 2 -C g −1 SOC at 10 • C and from 12 to 423 mg g −1 at 20 • C. This variation occurring under controlled conditions suggests that besides soil water regime, weather and management, SOM composition may be an underestimated factor that determines CO 2 fluxes measured in field experiments. However, correlations between the investigated chemical SOM characteristics and CO 2 emissions were weak. The latter also did not show a dependence on land-use type, although peat under forest was decomposed the least. High CO 2 emissions in some topsoils were probably related to the accrual of labile crop residues. A comparison with published CO 2 rates from incubated mineral soils indicated no difference in SOM decomposability between these soil classes, suggesting that accumulation of recent, labile plant materials that presumably account for most of the evolved CO 2 is not systematically different between mineral and organic soils. In our data set, temperature sensitivity of decomposition (Q 10 on average 2.57 ± 0.05) was the same for all land uses but lowest below 60 cm in croplands and grasslands. This, in turn, indicates a relative accumulation of recalcitrant peat in topsoils.

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Section: Introductionmentioning

confidence: 60%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Peat decomposability in managed organic soils in relation to land use, organic matter composition and temperature

et al. 2018

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“…This variation of NEE by the choice of gap filling is in the range of recently reported uncertainties of discontinuous manual chamber data (Moffat et al, submitted). Interestingly, this variation is also in the same order of magnitude as the uncertainty reported with IPCC emission factors from organic soils ( Blain et al, ; Drösler et al, ) and other aggregated data sets and meta‐analyses of terrestrial C sources and sinks ( Wilson et al, ; Tiemeyer et al, ). Although very speculative, we propose that the S/C/I approach is likely closer to the true NEE of our system because studies using different methodologies (chamber measurements, long‐term crop records/soil sampling, and eddy covariance measurements) from agro‐ecosystems with forage crops ( e.g ., ryegrass and lucerne) generally estimate an NEE in the range of –100 to –400 g C m −2 ( Byrne et al, ; Bolinder et al, ; Gilmanov et al, ).…”

Section: Discussionmentioning

confidence: 99%

Divergent NEE balances from manual‐chamber CO₂ fluxes linked to different measurement and gap‐filling strategies: A source for uncertainty of estimated terrestrial C sources and sinks?

Huth

Vaidya

Hoffmann

et al. 2017

J. Plant Nutr. Soil Sci.

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Manual closed‐chamber measurements are commonly used to quantify annual net CO2 ecosystem exchange (NEE) in a wide range of terrestrial ecosystems. However, differences in both the acquisition and gap filling of manual closed‐chamber data are large in the existing literature, complicating inter‐study comparisons and meta analyses. The aim of this study was to compare common approaches for quantifying CO2 exchange at three methodological levels. (1) The first level included two different CO2 flux measurement methods: one via measurements during mid‐day applying net coverages (mid‐day approach) and one via measurements from sunrise to noon (sunrise approach) to capture a span of light conditions for measurements of NEE with transparent chambers. (2) The second level included three different methods of pooling measured ecosystem respiration (RECO) fluxes for empirical modeling of RECO: campaign‐wise (19 single‐measurement‐day RECO models), season‐wise (one RECO model for the entire study period), and cluster‐wise (two RECO models representing a low and a high vegetation status). (3) The third level included two different methods of deriving fluxes of gross primary production (GPP): by subtracting either proximately measured RECO fluxes (direct GPP modeling) or empirically modeled RECO fluxes from measured NEE fluxes (indirect GPP modeling). Measurements were made during 2013–2014 in a lucerne‐clover‐grass field in NE Germany. Across the different combinations of measurement and gap‐filling options, the NEE balances of the agricultural field diverged strongly (–200 to 425 g CO2‐C m−2). NEE balances were most similar to previous studies when derived from sunrise measurements and indirect GPP modeling. Overall, the large variation in NEE balances resulting from different data‐acquisition or gap‐filling strategies indicates that these methodological decisions should be made very carefully and that they likely add to the overall uncertainty of greenhouse gas emission factors. Preferably, a standard approach should be developed to reduce the uncertainty of upscaled estimates.

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“…() and Tiemeyer at al. () for permanent grasslands on fen soils in Denmark and Germany, respectively, obtained by a similar approach. NEE budgets for site UG were smaller compared to site GW, which confirms the general assumption for rewetted peatlands ( Augustin and Joosten , ).…”

Section: Discussionmentioning

confidence: 98%

Comparing chamber and eddy covariance based net ecosystem CO₂ exchange of fen soils

Poyda

Reinsch

Skinner

et al. 2017

J. Plant Nutr. Soil Sci.

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Due to their high emission potential, the reporting of CO2 emissions from peatlands requires exact emission factors for different land use categories. Recently used emission factors are mainly based on CO2 flux measurements by chamber techniques or the micrometeorological eddy covariance (EC) method. However, evidence about the reliability and comparability of annual CO2 balances based on these methods is scarce. Therefore, manual chamber measurements of ecosystem respiration (RECO) and net ecosystem exchange (NEE) were conducted for two years (March 2012–April 2014) to model annual balances of two sites on fen soils with different land use intensity in northern Germany: an unutilized and rewetted grassland (UG) and an intensively utilized wet grassland (GW). Simultaneously, EC measurements of NEE were conducted on the sites. Two reasons for occasionally great deviations in NEE between the methods could be observed: (1) the accordance of both methods was most hampered during transition periods such as the beginning of the growing season and the onset of regrowth after a grassland defoliation due to different spatial scales of EC and chamber measurements and (2) RECO and gross primary production (GPP) partitioned from EC NEE measurements were systematically lower than those from the chamber‐based model, which could be a result of the EC energy balance gap. Differences were more pronounced for the managed site GW as a result of more frequent regrowth periods. It is concluded that the EC and chamber method can show comparable results for the CO2 exchange of grasslands on fen soils when the limitations of both methods are known and considered for the reporting of emission factors. These limitations are due to energy balance closure and potentially biased footprints for EC and a restricted representativeness especially during early stages of plant development for the chamber method.

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High emissions of greenhouse gases from grasslands on peat and other organic soils

Cited by 178 publications

References 53 publications

Peat decomposability in managed organic soils in relation to land use, organic matter composition and temperature

Peat decomposability in managed organic soils in relation to land use, organic matter composition and temperature

Divergent NEE balances from manual‐chamber CO₂ fluxes linked to different measurement and gap‐filling strategies: A source for uncertainty of estimated terrestrial C sources and sinks?

Comparing chamber and eddy covariance based net ecosystem CO₂ exchange of fen soils

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High emissions of greenhouse gases from grasslands on peat and other organic soils

Cited by 178 publications

References 53 publications

Peat decomposability in managed organic soils in relation to land use, organic matter composition and temperature

Peat decomposability in managed organic soils in relation to land use, organic matter composition and temperature

Divergent NEE balances from manual‐chamber CO2 fluxes linked to different measurement and gap‐filling strategies: A source for uncertainty of estimated terrestrial C sources and sinks?

Comparing chamber and eddy covariance based net ecosystem CO2 exchange of fen soils

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Divergent NEE balances from manual‐chamber CO₂ fluxes linked to different measurement and gap‐filling strategies: A source for uncertainty of estimated terrestrial C sources and sinks?

Comparing chamber and eddy covariance based net ecosystem CO₂ exchange of fen soils