我组成员在 Journal of Geophysical Research Biogeosciences 上发表文章:Chenxia Su, Ronghua �������Kang, Weixing Zhu, Wentao Huang, Linlin Song, Ang Wang, Dongwei Liu, Zhi Quan, Feifei Zhu, Pingq���ing Fu, Yunting Fang. δ15N of nitric oxide �������produced under aerobic or anaerobic conditions ������from seven soils and their associated N isotope fractionations [J]. Journal of Geophysical Research Biogeosciences, 2020.
文章链接:
Measuring the nitrogen isotope compositions (δ15N) o�����f nitric oxide (NO) from different sources helps to quantify the relative contributions of ����atmospheric NOx. Soil is one of the most important ������sources of atmospheric N����Ox, but only limited measurements on the δ15N of soil-emitted NO exist, hampering our ability to partition sources to air pollution. Here we conducted soil incubations to measure t�����he δ15N-NO under defined aerobic or anaerobic conditions, favoring either nitrification or denitrification. Soils were collected from����� seven sites spanning three ecosystems in northern China (two agricultural, two forest, and thr�������ee grassland sites). We found that the δ15N-NO and their associated N isotope fractionations were significantly different between anaerobic and aerob�������ic conditions in seven soils. Under aerobic condition, the δ15N-NO ranged from -62‰ to -50‰ (averaged -56 ± 4‰), being significantly more negative (by 23‰) than those under anaerobic c�������ondition (-45‰ to -23‰, averaged-33 ± 7����‰). The apparent N isotope fractionation for NO production under aerobic condition (15εaerobic =������ 61 ± 3‰) was significantly �����higher (by 26‰) than under anaerobic condition (15εanaerobic �����;= 35 ± 6‰), with a small variability among ecosystem types. Our study demonstrates that the δ15N-NO from different soils are very different from fuel combus�����������tions (mainly from 0‰ to +20‰), supporting that measuring 15N is a useful tool to partition the contributions of soil NO to atmospheric N����Ox. Our results also imply δ15N-NO produced by nitrification and denitrification distinctly different, as these two processes are dominant processes producing NO under aerobic and anaerobic conditions, respectively.
