- Qiu, Yunpeng;
- Zhang, Yi;
- Zhang, Kangcheng;
- Xu, Xinyu;
- Zhao, Yunfeng;
- Bai, Tongshuo;
- Zhao, Yexin;
- Wang, Hao;
- Sheng, Xiongjie;
- Bloszies, Sean;
- Gillespie, Christopher;
- He, Tangqing;
- Wang, Yang;
- Chen, Huaihai;
- Guo, Lijin;
- Song, He;
- Ye, Chenglong;
- Wang, Yi;
- Woodley, Alex;
- Guo, Jingheng;
- Cheng, Lei;
- Bai, Yongfei;
- Zhu, Yongguan;
- Hallin, Sara;
- Hu, Shuijin;
- Firestone, Mary
Global potent greenhouse gas nitrous oxide (N2O) emissions from soil are accelerating, with increases in the proportion of reactive nitrogen emitted as N2O, i.e., N2O emission factor (EF). Yet, the primary controls and underlying mechanisms of EFs remain unresolved. Based on two independent but complementary global syntheses, and three field studies determining effects of acidity on N2O EFs and soil denitrifying microorganisms, we show that soil pH predominantly controls N2O EFs and emissions by affecting the denitrifier community composition. Analysis of 5438 paired data points of N2O emission fluxes revealed a hump-shaped relationship between soil pH and EFs, with the highest EFs occurring in moderately acidic soils that favored N2O-producing over N2O-consuming microorganisms, and induced high N2O emissions. Our results illustrate that soil pH has a unimodal relationship with soil denitrifiers and EFs, and the net N2O emission depends on both the N2O/(N2O + N2) ratio and overall denitrification rate. These findings can inform strategies to predict and mitigate soil N2O emissions under future nitrogen input scenarios.