Soil moisture-atmosphere feedback dominates land carbon uptake variability

Year-to-year changes in carbon uptake by terrestrial ecosystems have an essential role in determining atmospheric carbon dioxide concentrations(1). It remains uncertain to what extent temperature and water availability can explain these variations at the global scale(2-5). Here we use factorial climate model simulations(6) and show that variability in soil moisture drives 90 per cent of the inter-annual variability in global land carbon uptake, mainly through its impact on photosynthesis. We find that most of this ecosystem response occurs indirectly as soil moisture-atmosphere feedback amplifies temperature and humidity anomalies and enhances the direct effects of soil water stress. The strength of this feedback mechanism explains why coupled climate models indicate that soil moisture has a dominant role(4), which is not readily apparent from land surface model simulations and observational analyses(2,5). These findings highlight the need to account for feedback between soil and atmospheric dryness when estimating the response of the carbon cycle to climatic change globally(5,7), as well as when conducting field-scale investigations of the response of the ecosystem to droughts(8,9). Our results show that most of the global variability in modelled land carbon uptake is driven by temperature and vapour pressure deficit effects that are controlled by soil moisture.

Automated summary

The study demonstrates that global land carbon uptake variability is mainly driven by soil moisture, which indirectly affects photosynthesis. The soil moisture-atmosphere feedback mechanism amplifies temperature and humidity anomalies, enhancing the direct impact of soil water stress.