Evaluation of a portable chamber system for soil CO2 efflux measurement and the potential errors caused by internal compensation and water vapor dilution

Matsuura, Shoji; Mori, Akinori; Hojito, Masayuki; Kanno, Tsutomu; Sasaki, Hidetada

doi:10.2480/agrmet.67.3.7

Cited by 7 publications

(4 citation statements)

References 12 publications

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“…Only in advective high-T. Eickenscheidt et al: The greenhouse gas balance of a drained fen peatland flux situations when the rate of increasing water vapor is less than 1 % of the rate of increasing chamber CO 2 may dilution effects be ignored. This finding was also confirmed by Matsuura et al (2011). However, neither corrections for cross-sensitivity and band broadening nor a dilution correction were applied in the present study.…”

Section: Uncertainties In Ghg Fluxes and Modelingsupporting

confidence: 84%

The greenhouse gas balance of a drained fen peatland is mainly controlled by land-use rather than soil organic carbon content

2015

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Abstract. Drained organic soils are considered to be hotspots for greenhouse gas (GHG) emissions. Arable lands and intensively used grasslands, in particular, have been regarded as the main producers of carbon dioxide (CO2) and nitrous oxide (N2O). However, GHG balances of former peatlands and associated organic soils not considered to be peatland according to the definition of the Intergovernmental Panel on Climate Change (IPCC) have not been investigated so far. Therefore, our study addressed the question to what extent the soil organic carbon (SOC) content affects the GHG release of drained organic soils under two different land-use types (arable land and intensively used grassland). Both land-use types were established on a Mollic Gleysol (labeled Cmedium) as well as on a Sapric Histosol (labeled Chigh). The two soil types differed significantly in their SOC contents in the topsoil (Cmedium: 9.4–10.9 % SOC; Chigh: 16.1–17.2 % SOC). We determined GHG fluxes over a period of 1 or 2 years in case of N2O or methane (CH4) and CO2, respectively. The daily and annual net ecosystem exchange (NEE) of CO2 was determined by measuring NEE and the ecosystem respiration (RECO) with the closed dynamic chamber technique and by modeling the RECO and the gross primary production (GPP). N2O and CH4 were measured with the static closed chamber technique. Estimated NEE of CO2 differed significantly between the two land-use types, with lower NEE values (−6 to 1707 g CO2-C m−2 yr−1) at the arable sites and higher values (1354 to 1823 g CO2-C m−2 yr−1) at the grassland sites. No effect on NEE was found regarding the SOC content. Significantly higher annual N2O exchange rates were observed at the arable sites (0.23–0.86 g N m−2 yr−1) than at the grassland sites (0.12–0.31 g N m−2 yr−1). Furthermore, N2O fluxes from the Chigh sites significantly exceeded those of the Cmedium sites. CH4 fluxes were found to be close to zero at all plots. Estimated global warming potential, calculated for a time horizon of 100 years (GWP100) revealed a very high release of GHGs from all plots ranging from 1837 to 7095 g CO2 eq. m−2 yr−1. Calculated global warming potential (GWP) values did not differ between soil types and partly exceeded the IPCC default emission factors of the Tier 1 approach by far. However, despite being subject to high uncertainties, the results clearly highlight the importance of adjusting the IPCC guidelines for organic soils not falling under the definition in order to avoid a significant underestimation of GHG emissions in the corresponding sectors of the national climate reporting. Furthermore, the present results revealed that mainly the type of land-use, including the management type, and not the SOC content is responsible for the height of GHG exchange from intensive farming on drained organic soils.

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Section: Uncertainties In Ghg Fluxes and Modelingsupporting

confidence: 84%

The greenhouse gas balance of a drained fen peatland is mainly controlled by land-use rather than soil organic carbon content

2015

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“…Both linear and quadratic rates are calculated, and model parameters are stored for the following model-selection steps. Subsequently, rates are corrected for an increase of water vapour concentrations as dilution by water molecules can significantly reduce CO 2 flux estimates (Matsuura et al, 2011).…”

Section: In Situ Fluxesmentioning

confidence: 99%

Blanket bog CO₂ flux driven by plant functional type during summer drought

et al. 2022

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Recent climate predictions for the United Kingdom expect a nationwide shift towards drier and warmer summers, increasing the risk of more frequent and severe drought events. Such shifts in weather patterns impede functioning of global peatlands, especially rare intact blanket bogs abundant in Scotland and representing nearly a quarter of the UK's soil carbon. In this in situ study, carbon dioxide (CO 2 ) fluxes from dominant peatland plant functional types (PFTs) such as Sphagnum spp., graminoids, ericoids and other key cover types (i.e., pools and bare peat) were measured and compared across upland and low-lying blanket bog margins and centres, immediately before and during a summer drought in 2018, and over the subsequent year. During that period, most sites acted as net sources of CO 2 to the atmosphere. Our results showed that net ecosystem exchange (NEE) was limited by water availability during the drought, with ericoid shrubs showing the highest drought resilience, followed by graminoids (which were still limited in GPP in 2019) and Sphagnum mosses. Diverging NEE estimates were observed across centre and margin areas of the blanket bogs, with highest variability across the upland site where signs of active erosion were visible. Overall, our study suggests that estimating growing season carbon fluxes from in situ peatland PFT and cover types can help us better understand global climate change impacts on the dynamics and trajectories of peatland C cycles.

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“…Details of the system were presented previously by Matsuura et al 2011 . Briefly, the system consisted of an infrared CO 2 gas analyzer GMP343 diffusion model, Vaisala, Helsinki, Finland and a temperature/humidity sensor HMP75, Vaisala that penetrated through a chamber lid white acrylic disk, diameter 465 mm ; a data-logging device MI70, Vaisala for collecting data of CO 2 concentration, air temperature, and relative humidity inside a chamber; a temperature/pressure sensor RS-12P, Espec Mic, Oguchi, Japan ; and cylindrical stainless-steel chambers inside diameter 390 -415 mm, height 300 mm .…”

Section: Chamber Measurementsmentioning

confidence: 99%

Short-term effects of grassland renovation on CO<SUB>2</SUB> exchange of grasslands in a temperate humid region

Matsuura

Nakao

Hojito

2017

J. Agric. Meteorol.

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To investigate the short-term effects of grassland renovation on carbon dioxide CO 2 exchange of intensively managed grasslands in Japan, we conducted CO 2 flux measurements during the renovation process by using the eddy covariance and closed chamber methods in 2007, 2012, and 2013. The flux measurements were conducted at three grassland fi elds: two fi elds used for cutting, one receiving only chemical fertilizer CF and the other receiving composted cattle manure CM annually, and one fi eld used for grazing GM . Chamber measurements revealed fl ushes of CO 2 after plowing 14.45 -23.94 μmol m 2 s 1 and subsequent disk harrowing 7.36 μmol m 2 s 1 , in CF followed by rapid drops of CO 2 flux, which were local and temporary phenomena. The mean CO 2 losses during renovation periods were calculated as 4.52 -4.74, 6.00 -6.81, and 4.57 g C m 2 d 1 in CF, CM, and GM, respectively; CF and CM calculation is based on eddy covariance measurements, including temporal fl ux variations and representing footprint areas. The amount of carbon input during renovation including non-harvested grass biomass stubble and roots and applied manure was estimated as 2.24 -3.50 and 6.17 -8.77 Mg C ha 1 in CF and CM, respectively. Among them, carbon derived from plowed roots and manure is presumably resistant in soil, contributing to long-term soil organic carbon SOC accumulation. Our results also indicate that grassland renovation work does not affect short-term net CO 2 loss signifi cantly, although it affects CO 2 emissions to a certain extent. We can therefore say that net CO 2 loss during renovation is mainly brought by the absence of vegetation in this site. Grasses contribute SOC accumulation through biomass allocation belowground; and it is thus recommended to shorten grassland renovation period, the duration without photosynthesis, to reduce CO 2 loss associated with grassland renovation.

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Evaluation of a portable chamber system for soil CO2 efflux measurement and the potential errors caused by internal compensation and water vapor dilution

Cited by 7 publications

References 12 publications

The greenhouse gas balance of a drained fen peatland is mainly controlled by land-use rather than soil organic carbon content

The greenhouse gas balance of a drained fen peatland is mainly controlled by land-use rather than soil organic carbon content

Blanket bog CO₂ flux driven by plant functional type during summer drought

Short-term effects of grassland renovation on CO<SUB>2</SUB> exchange of grasslands in a temperate humid region

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Evaluation of a portable chamber system for soil CO2 efflux measurement and the potential errors caused by internal compensation and water vapor dilution

Cited by 7 publications

References 12 publications

The greenhouse gas balance of a drained fen peatland is mainly controlled by land-use rather than soil organic carbon content

The greenhouse gas balance of a drained fen peatland is mainly controlled by land-use rather than soil organic carbon content

Blanket bog CO2 flux driven by plant functional type during summer drought

Short-term effects of grassland renovation on CO<SUB>2</SUB> exchange of grasslands in a temperate humid region

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Blanket bog CO₂ flux driven by plant functional type during summer drought