Atmospheric deposition of organic nitrogen (ON) plays a crucial role in the global nitrogen cycle. Surface measurements showed that 2% to 70% of the local atmospheric deposition flux of total nitrogen was organic. However, previous models have largely neglected the spatial and chemical variations of atmospheric ON, leading to inadequate assessment of its global impacts.
The scientists from SUSTech and HKUST developed a comprehensive global model of atmospheric gaseous and particulate ON, incorporating the latest knowledge on emissions and secondary formations. Their simulated surface concentrations of atmospheric particulate ON (ONp) were highly consistent with global observations, a feat that had not been achieved previously. Additionally, their simulated atmospheric deposition flux aligned with global observations within an order of magnitude. The scientists estimated that the global atmospheric ON deposition was 26 Tg N yr-1. This majority of this deposition (23 Tg N yr-1) occurred in the form of ON aerosol and accounted for 19% of the global atmospheric total N deposition (124 Tg N yr-1). The main sources of ON aerosols were wildfires, ocean emissions, and secondary formation.
“Our simulation showed that the deposition of ON aerosol from the atmosphere is a crucial external source of nitrogen to nitrogen-limited ecosystems worldwide, such as the boreal forests, tundras, and the Arctic Ocean,” Fu says. In a future warming climate, wildfires will likely become more frequent and intense. Climate warming will also lead to surface ocean stratification, making atmospheric ON deposition an increasingly important source of nitrogen to these ecosystems. “We need to further examine the environmental impacts of atmospheric ON aerosol and how those impacts respond to climate change.”