Abstract
Abstract. The efflux of carbon dioxide (CO2) from soils influences atmospheric CO2 concentrations and thereby climate change. The partitioning of inorganic carbon (C) fluxes in the vadose zone between emission to the atmosphere and to the groundwater was investigated to reveal controlling underlying mechanisms. Carbon dioxide partial pressure in the soil gas (pCO2), alkalinity, soil moisture and temperature were measured over depth and time in unplanted and planted (barley) mesocosms. The dissolved inorganic carbon (DIC) percolation flux was calculated from the pCO2, alkalinity and the water flux at the mesocosm bottom. Carbon dioxide exchange between the soil surface and the atmosphere was measured at regular intervals. The soil diffusivity was determined from soil radon-222 (222Rn) emanation rates and soil air Rn concentration profiles and was used in conjunction with measured pCO2 gradients to calculate the soil CO2 production. Carbon dioxide fluxes were modeled using the HP1 module of the Hydrus 1-D software. The average CO2 effluxes to the atmosphere from unplanted and planted mesocosm ecosystems during 78 days of experiment were 0.1 ± 0.07 and 4.9 ± 0.07 μmol C m−2 s−1, respectively, and grossly exceeded the corresponding DIC percolation fluxes of 0.01 ± 0.004 and 0.06 ± 0.03 μmol C m−2 s−1. Plant biomass was high in the mesocosms as compared to a standard field situation. Post-harvest soil respiration (Rs) was only 10% of the Rs during plant growth, while the post-harvest DIC percolation flux was more than one-third of the flux during growth. The Rs was controlled by production and diffusivity of CO2 in the soil. The DIC percolation flux was largely controlled by the pCO2 and the drainage flux due to low solution pH. Modeling suggested that increasing soil alkalinity during plant growth was due to nutrient buffering during root nitrate uptake.
Highlights
The global flux of carbon dioxide (CO2) from the soil to the atmosphere amounts to 59–76.5 Gt carbon (C) yr−1 and is one of the largest fluxes in the global C budget (Raich and Potter, 1995; Houghton, 2007)
The dissolved inorganic carbon (DIC) percolation flux of ∼ 5 mmol C m−2 d−1 during barley growth was ∼ 1.6–2.0 % of the Rs at increased plant biomass and elevated soil pCO2 compared to the field situation
The magnitude of the DIC percolation flux was lowered to ∼ 2.5 mmol C m−2 d−1 but the importance of DIC percolation flux for the overall cropland CO2 emission increased to ∼ 6–7 % of the Rs
Summary
The global flux of carbon dioxide (CO2) from the soil to the atmosphere amounts to 59–76.5 Gt carbon (C) yr−1 and is one of the largest fluxes in the global C budget (Raich and Potter, 1995; Houghton, 2007) Agriculture strongly enhances this flux, accounting for 10–12 % of global anthropogenic emissions (Robertson et al, 2000; Barker et al, 2007; Vermeulen et al, 2012). In the light of the climate change induced by the present atmospheric concentration of CO2 of 400 ppm and its increment rate of ∼ 2 ppm yr−1 (IPCC, 2007; Lal, 2011), the magnitudes and underlying mechanisms of the soil CO2 effluxes to the atmosphere and groundwater from agricultural systems are of crucial importance for prediction of the climate forcing. The present study explores the total CO2 emission for a cropland mesocosm system and investigates the underlying mechanisms
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