Effects of soil O2 on CO2 and N2O concentration change under extreme precipitation
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Abstract
Agricultural soils play an important role in global greenhouse gases emissions. Precipitation is a critical factor driving soil greenhouse gases emissions in arid and semi-arid regions; however, the mechanism of greenhouse gas generation and emission under extreme precipitation has not been well documented. The aim of this study was to determine the relationships between greenhouse gases (CO2, N2O) concentrations and fluxes and soil O2 dynamics under extreme precipitation. Based on an extreme precipitation scenario (100 mm), a simulation experiment of soil column was established at the Changwu Station, and high-frequency measurements of soil O2, CO2, and N2O concentrations and CO2 and N2O fluxes were conducted under three soil management practices (no fertilization, nitrogen fertilization, and nitrogen fertilization plus straws incorporation). The results showed that N2O cumulative emissions in no fertilization, nitrogen fertilization, and nitrogen fertilization plus straws incorporation under extreme precipitation increased by 310%, 440%, and 190% of those under light precipitation (10 mm), respectively. However, CO2 cumulative emissions in no fertilization, nitrogen fertilization, and nitrogen fertilization plus straws incorporation increased by 27%, 1%, and −11%, respectively, compared to that under light precipitation. The surface CO2 and N2O fluxes followed basically CO2 and N2O concentrations dynamics in the soil, and there was a significant positive correlation between soil surface fluxes and belowground concentrations. Under extreme precipitation events, soil O2 concentrations sharply decreased and progressively recovered to the initial level, and concomitantly, soil CO2 and N2O concentrations peaked, showing an opposite dynamic pattern. In addition, the timing of the three gases concentrations under extreme precipitation was delayed compared to that under light precipitation events. Soil O2 concentrations were negatively correlated with CO2 and N2O concentrations. Soil CO2 concentrations followed a logistic growth pattern with decreasing O2 concentrations, and N2O concentrations followed an exponential growth pattern with decreasing O2 concentrations. Therefore, soil CO2 and N2O production and emissions are strongly related to soil O2 concentration dynamics during extreme precipitation events. These results will help clarify the mechanism of greenhouse gases emissions from rainfed croplands in the Loess Plateau.
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