Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
The importance of climate change and nitrogen use efficiency for future nitrous oxide emissions from agriculture
Nitrous oxide (N _2 O) is an important greenhouse gas and ozone depleting substance. Previous projections of agricultural N _2 O (the dominant anthropogenic source) show emissions changing in tandem, or at a faster rate than changes in nitrogen (N) consumption. However, recent studies suggest that the carbon dioxide (CO _2 ) fertilization effect may increase plant N uptake, which could decrease soil N losses and dampen increases in N _2 O. To evaluate this hypothesis at a global scale, we use a process-based land model with a coupled carbon-nitrogen cycle to examine how changes in climatic factors, land-use, and N application rates could affect agricultural N _2 O emissions by 2050. Assuming little improvement in N use efficiency (NUE), the model projects a 24%–31% increase in global agricultural N _2 O emissions by 2040–2050 depending on the climate scenario—a relatively moderate increase compared to the projected increases in N inputs (42%–44%) and previously published emissions projections (38%–75%). This occurs largely because the CO _2 fertilization effect enhances plant N uptake in several regions, which subsequently dampens N _2 O emissions. And yet, improvements in NUE could still deliver important environmental benefits by 2050: equivalent to 10 Pg CO _2 equivalent and 0.6 Tg ozone depletion potential.
The importance of climate change and nitrogen use efficiency for future nitrous oxide emissions from agriculture
Nitrous oxide (N _2 O) is an important greenhouse gas and ozone depleting substance. Previous projections of agricultural N _2 O (the dominant anthropogenic source) show emissions changing in tandem, or at a faster rate than changes in nitrogen (N) consumption. However, recent studies suggest that the carbon dioxide (CO _2 ) fertilization effect may increase plant N uptake, which could decrease soil N losses and dampen increases in N _2 O. To evaluate this hypothesis at a global scale, we use a process-based land model with a coupled carbon-nitrogen cycle to examine how changes in climatic factors, land-use, and N application rates could affect agricultural N _2 O emissions by 2050. Assuming little improvement in N use efficiency (NUE), the model projects a 24%–31% increase in global agricultural N _2 O emissions by 2040–2050 depending on the climate scenario—a relatively moderate increase compared to the projected increases in N inputs (42%–44%) and previously published emissions projections (38%–75%). This occurs largely because the CO _2 fertilization effect enhances plant N uptake in several regions, which subsequently dampens N _2 O emissions. And yet, improvements in NUE could still deliver important environmental benefits by 2050: equivalent to 10 Pg CO _2 equivalent and 0.6 Tg ozone depletion potential.
The importance of climate change and nitrogen use efficiency for future nitrous oxide emissions from agriculture
David R Kanter (Autor:in) / Xin Zhang (Autor:in) / Denise L Mauzerall (Autor:in) / Sergey Malyshev (Autor:in) / Elena Shevliakova (Autor:in)
2016
Aufsatz (Zeitschrift)
Elektronische Ressource
Unbekannt
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