Litcius/Paper detail

Saturation response of enhanced vegetation productivity attributes to intricate interactions

Xihong Lian, Limin Jiao, Zejin Liu

2022Global Change Biology33 citationsDOI

Abstract

Abstract Evidence for the multifaceted responses of terrestrial ecosystems has been shown by the weakening of CO 2 fertilization‐induced and warming‐controlled productivity gains. The intricate relationship between vegetation productivity and various environmental controls still remains elusive spatially. Here several inherent preponderances make China a natural experimental setting to investigate the interaction and relative contributions of five drivers to gross primary productivity for the period from 1982 to 2018 (i.e., elevated atmospheric CO 2 concentrations, climate change, nutrient availability, anthropogenic land use change, and soil moisture) by coupling multiple long‐term datasets. Despite a strikingly prominent enhancement of vegetation productivity in China, it exhibits similar saturation responses to the aforementioned environmental drivers (elevated CO 2 , climatic factors, and soil moisture). The CO 2 fertilization‐dominated network explains the long‐term variations in vegetation productivity in humid regions, but its effect is clearly attenuated or even absent in arid and alpine environments controlled by climate and soil moisture. Divergence in interactions also provides distinct evidence that water availability plays an essential role in limiting the potential effects of climate change and elevated CO 2 concentrations on vegetation productivity. Unprecedented industrialization and dramatic surface changes may have breached critical thresholds of terrestrial ecosystems under the diverse natural environment and thus forced a shift from a period dominated by CO 2 fertilization to a period with nonlinear interactions. These findings suggest that future benefits in terrestrial ecosystems are likely to be counteracted by uncertainties in the complicated network, implying an increasing reliance on human societies to combat potential risks. Our results therefore highlight the need to account for the intricate interactions globally and thus incorporate them into mitigation and adaptation policies.

Topics & Concepts

Environmental scienceEcosystemProductivityVegetation (pathology)Climate changeEcologyTerrestrial ecosystemAlternative stable stateGlobal changeEnvironmental changePrimary productionAridBiologyEconomicsPathologyMedicineMacroeconomicsPlant Water Relations and Carbon DynamicsPlant responses to elevated CO2Ecology and Vegetation Dynamics Studies