<p>Nitrous oxide fluxes from urine patches (F(N<sub>2</sub>O)<sub>urine</sub>) of grazing livestock are variable over time due to fluctuations in driving parameters, such as soil temperature, water-filled pore space (WFPS), and availability of the source substrates ammonium and nitrate. Therefore, the frequency and timing of flux measurements after urine application are important when determining cumulative F(N<sub>2</sub>O)<sub>urine</sub>. In this study, F(N<sub>2</sub>O)<sub>urine</sub> was measured in eight experiments at high temporal frequency using an automatic chamber system in a pasture located in Switzerland. A driver analysis using random forest identified the time since urine application as most important predictor for F(N<sub>2</sub>O)<sub>urine</sub>. The exponential decay in F(N<sub>2</sub>O)<sub>urine</sub> after urine addition was in parallel to decreasing soil ammonium but anticorrelated to nitrate concentration, suggesting that nitrification and nitrifier denitrification are major source processes. Since nitrate showed elevated concentrations up to 122&#xa0;days after application, bacterial denitrification is most likely responsible for late F(N<sub>2</sub>O)<sub>urine</sub> peaks following an increase of WFPS. The isotopic composition of the emitted N<sub>2</sub>O indicates that nitrification dominates the N<sub>2</sub>O production immediately after urine application, while bacterial denitrification and nitrifier denitrification become more important with increasing time since urine application. The observed high-frequency emission time series were also used to simulate typical low-frequent manual chamber sampling schedules. They led to considerable deviations (up to ± 30%) of the time-integrated N<sub>2</sub>O emission. However, the average bias was considerably smaller (− 5%) for the prescribed sampling schedule, indicating that manual chamber measurements can reasonably quantify average total N<sub>2</sub>O emissions from urine patches under the present pedoclimatic conditions.</p>

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Temporal dynamics of N2O emissions from pasture urine patches: drivers and source processes

  • Lena Barczyk,
  • Markus Jocher,
  • Julius Havsteen,
  • Joachim Mohn,
  • Johan Six,
  • Christof Ammann

摘要

Nitrous oxide fluxes from urine patches (F(N2O)urine) of grazing livestock are variable over time due to fluctuations in driving parameters, such as soil temperature, water-filled pore space (WFPS), and availability of the source substrates ammonium and nitrate. Therefore, the frequency and timing of flux measurements after urine application are important when determining cumulative F(N2O)urine. In this study, F(N2O)urine was measured in eight experiments at high temporal frequency using an automatic chamber system in a pasture located in Switzerland. A driver analysis using random forest identified the time since urine application as most important predictor for F(N2O)urine. The exponential decay in F(N2O)urine after urine addition was in parallel to decreasing soil ammonium but anticorrelated to nitrate concentration, suggesting that nitrification and nitrifier denitrification are major source processes. Since nitrate showed elevated concentrations up to 122 days after application, bacterial denitrification is most likely responsible for late F(N2O)urine peaks following an increase of WFPS. The isotopic composition of the emitted N2O indicates that nitrification dominates the N2O production immediately after urine application, while bacterial denitrification and nitrifier denitrification become more important with increasing time since urine application. The observed high-frequency emission time series were also used to simulate typical low-frequent manual chamber sampling schedules. They led to considerable deviations (up to ± 30%) of the time-integrated N2O emission. However, the average bias was considerably smaller (− 5%) for the prescribed sampling schedule, indicating that manual chamber measurements can reasonably quantify average total N2O emissions from urine patches under the present pedoclimatic conditions.