Abstract
Abstract. Tea fields emit large amounts of nitrous oxide (N2O) to the atmosphere. Obtaining accurate estimations of N2O emissions from tea-planted soils is challenging due to strong spatial variability. We examined the spatial variability in N2O emissions from a red-soil tea field in Hunan Province, China, on 22 April 2012 (in a wet season) using 147 static mini chambers approximately regular gridded in a 4.0 ha tea field. The N2O fluxes for a 30 min snapshot (10:00–10:30 a.m.) ranged from −1.73 to 1659.11 g N ha−1 d−1 and were positively skewed with an average flux of 102.24 g N ha−1 d−1. The N2O flux data were transformed to a normal distribution by using a logit function. The geostatistical analyses of our data indicated that the logit-transformed N2O fluxes (FLUX30t) exhibited strong spatial autocorrelation, which was characterized by an exponential semivariogram model with an effective range of 25.2 m. As observed in the wet season, the logit-transformed soil ammonium-N (NH4Nt), soil nitrate-N (NO3Nt), soil organic carbon (SOCt) and total soil nitrogen (TSNt) were all found to be significantly correlated with FLUX30t (r = 0.57–0.71, p < 0.001). Three spatial interpolation methods (ordinary kriging, regression kriging and cokriging) were applied to estimate the spatial distribution of N2O emissions over the study area. Cokriging with NH4Nt and NO3Nt as covariables (r = 0.74 and RMSE = 1.18) outperformed ordinary kriging (r = 0.18 and RMSE = 1.74), regression kriging with the sample position as a predictor (r = 0.49 and RMSE = 1.55) and cokriging with SOCt as a covariable (r = 0.58 and RMSE = 1.44). The predictions of the three kriging interpolation methods for the total N2O emissions of 4.0 ha tea field ranged from 148.2 to 208.1 g N d−1, based on the 30 min snapshots obtained during the wet season. Our findings suggested that to accurately estimate the total N2O emissions over a region, the environmental variables (e.g., soil properties) and the current land use pattern (e.g., tea row transects in the present study) must be included in spatial interpolation. Additionally, compared with other kriging approaches, the cokriging prediction approach showed great advantages in being easily deployed and, more importantly, providing accurate regional estimation of N2O emissions from tea-planted soils.
Highlights
According to the latest data, which show rapid increases in their atmospheric concentrations (IPCC, 2013), nitrous oxide (N2O), carbon dioxide (CO2) and methane (CH4) are three major greenhouse gases in the atmosphere that significantly contribute to global warming
dissolved organic carbon content (DOC) displayed a moderate coefficient of variation (CV) of 34.6 %, and the other variables had lower CVs (4.1–23.8 %)
We found that the CK method with NH4Nt and NO3Nt as covariables outperformed the CK method with SOCt as a covariable, indicating that the feature correlation was more important than the similarity of the spatial structure when selecting CK covariables
Summary
According to the latest data, which show rapid increases in their atmospheric concentrations (IPCC, 2013), nitrous oxide (N2O), carbon dioxide (CO2) and methane (CH4) are three major greenhouse gases in the atmosphere that significantly contribute to global warming. Among these major greenhouse gases, N2O has a very high radiative forcing per unit mass (265-fold stronger than CO2 on a 100-year horizon) and plays an important role in ozone depletion in the stratosphere (Ravishankara et al, 2009). Agricultural soils produce 2.8 (1.7–4.8) Tg of N2ON yr−1 (IPCC, 2013). Fu et al.: Wet-season spatial variability in N2O emissions
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