AUTHOR=Wang Fang , Yu Qibiao , Yan Weijin , Tian Siyu , Zhang Peipei , Wang Jianing TITLE=Basin-scale control on N2O loss rate and emission in the Changjiang River network, China JOURNAL=Frontiers in Marine Science VOLUME=9 YEAR=2022 URL=https://www.frontiersin.org/journals/marine-science/articles/10.3389/fmars.2022.1025912 DOI=10.3389/fmars.2022.1025912 ISSN=2296-7745 ABSTRACT=

Global riverine N₂O emissions have been made by several studies with great uncertainty. However, the regional N₂O budgets and patterns in large river networks is still unclear, due to the lacking understanding of in-river N₂O emission rate and well-classified river network water areas. Furthermore, the mass ratio of N₂O emission against nitrogen(N) load in river networks remains controversial. Here we report N₂O emissions from the largest river of China, the Changjiang River network, emphasizing the basin-scale control on riverine N₂O loss rate in response to increasing N loads and river size. We find the N₂O emission rate is negatively related to Strahler river orders, and positively related to N loading. The velocity (V_f) of N conversion into N₂O was 0.131-0.436 m yr^-1, and N₂O loss rate (ζ) was 0.27-37.64 ×10^-4 d^-1 and declined exponentially with water discharge. Both the loss rate and the mass ratio of N conversion into N₂O varied significantly at basin scale, indicating the diminishing capacity of river ecosystems to convert excess DIN into N₂O when N load increased as a direct result of human activities. Our study shows N₂O emission was 0.66 Gg N₂O-N (1Gg=10⁹g) in 1986 and increased to 10.3 Gg N₂O-N in 2014 for the whole Changjiang River network. We identified the headwater streams are hotspots of N₂O emission across the headwater stream to the estuary aquatic continuum. N₂O emission was about 0.82% - 5.31% of global riverine N₂O budget during 2010-2014. Our study suggested that an integrated approach in view of the riverine N loads and river hydrology is needed to improve estimates of riverine N₂O emissions.