Soil moisture-atmosphere interactions drive terrestrial carbon-water trade-offs
Wenqi Sun, Sha Zhou, Bofu Yu, Yao Zhang, Trevor F. Keenan, Bojie Fu
Abstract
Soil moisture is coupled with vegetation and atmosphere, influencing global cycling of water, carbon, and energy. However, it remains unclear how soil moisture-atmosphere interactions affect land-atmosphere carbon and water exchanges simultaneously. Using Earth system model experiments, we show widespread carbon-water trade-offs between net ecosystem production and precipitation-minus-evapotranspiration driven by soil moisture dynamics. Soil moisture positively controls net ecosystem production and negatively affects precipitation-minus-evapotranspiration, through direct soil water stress and indirect soil moisture-atmosphere feedbacks. While soil moisture variability magnifies the interannual variability of net ecosystem production, it moderates that of precipitation-minus-evapotranspiration over land. These opposing effects lead to a pronounced carbon-water trade-off, which originates from the interplay between carbon acquisition through photosynthesis and water extraction through evapotranspiration. This trade-off is projected to intensify in a warming and drying future, as soil moisture increasingly regulates carbon and water exchanges, posing a serious challenge to sustaining both terrestrial carbon sink and water supply. Soil moisture creates a trade-off between carbon and water exchanges, as wetter soils enhance net ecosystem production but reduce precipitation minus evaporation, according to Earth system model experiments on soil moisture-atmosphere interactions.