Abstract
The elevated atmospheric CO2 concentration (eCO2) is expected to increase the labile C input to the soil, which may stimulate microbial activity and soil N2O emissions derived from nitrification and denitrification. However, few studies studied the effect of eCO2 on N2O emissions from maize field under the free-air CO2 enrichment (FACE) conditions in the warm temperate zone. Here, we report a study conducted during the 12th summer maize season under long-term eCO2, aiming to investigate the effect of eCO2 on N2O emissions. Moreover, we tested zero and conventional N fertilization treatments, with maize being grown under either eCO2 or ambient CO2 (aCO2). We hypothesized that N2O emissions would be increased under eCO2 due to changes in soil labile C and mineral N derived from C-deposition, and that the increase would be larger when eCO2 was combined with conventional N fertilization. We also measured the activities of some soil extracellular enzymes, which could reflect soil C status. The results showed that, under eCO2, seasonal N2O and CO2 emissions increased by 12.4–15.6% (p < 0.1) and 13.8–18.5% (p < 0.05), respectively. N fertilization significantly increased the seasonal emissions of N2O and CO2 by 33.1–36.9% and 17.1–21.8%, respectively. Furthermore, the combination of eCO2 and N fertilization increased the intensity of soil N2O and CO2 emissions. The marginal significant increase in N2O emissions under eCO2 was mostly due to the lower soil water regime after fertilization in the study year. Dissolved organic C (DOC) and microbial biomass C (MBC) concentration showed a significant increase at most major stages, particularly at the tasseling stage during the summer maize growth period under eCO2. In contrast, soil mineral N showed a significant decrease under eCO2 particularly in the rhizospheric soils. The activities of C-related soil extracellular enzymes were significantly higher under eCO2, particularly at the tasseling stage, which coincided with concurrent increased DOC and MBC under eCO2. We conclude that eCO2 increases N2O emissions, and causes a higher increase when combined with N fertilization, but the increase extent of N2O emissions was influenced by environmental factors, especially by soil water, to a great extent. We highlighted the urgent need to monitor long-term N2O emissions and N2O production pathways in various hydrothermal regimes under eCO2.
Highlights
With the extensive combustion of fossil fuel and other anthropogenic activities since the industrial revolution, the atmospheric CO2 concentration has increased to 413.2 ppm in 2020 [1], and is predicted to reach 550 ppm in 2050 [2]
Soil N2O and CO2 Emission Fluxes during the Summer Maize Growth Period Soil N2O emission fluxes varied in the range of 10.4–634.7 μg N m−2 h−1 (Figure 2a)
For the top-dressing emission peak, it was higher by 23.1% and 25.4% under Elevated CO2 (eCO2) than ambient CO2 (aCO2) at zero N fertilization (ZN) and conventional N fertilization (CN) levels, respectively
Summary
With the extensive combustion of fossil fuel and other anthropogenic activities since the industrial revolution, the atmospheric CO2 concentration has increased to 413.2 ppm in 2020 [1], and is predicted to reach 550 ppm in 2050 [2]. Elevated CO2 (eCO2) may enhance plant photosynthesis and biomass production [3,4,5], and increase C input to soil by stimulating fine root turnover and rhizodeposition [6,7,8], which provide important available substrates for soil microbes. ECO2 may cause changes in soil C turnover, N availability and N2O emissions associated with microbial processes [9,10]. N2O emissions from croplands with N fertilization was responsible for 70% of global annual N2O emissions [11,12]. The effect of eCO2 on N2O emissions is receiving more attention, since it can address our current knowledge gap about soil feedback of global warming. The response of N2O emissions to eCO2 has varied in different studies, where the duration of the CO2 enrichment experiment and aboveground vegetation types were different [16,17,18]
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