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Optimizing water-use efficiency under elevated CO₂: A meta-analysis of crop type, soil modulation, and enrichment methods

Ali Mokhtar, Hongming He, Samar Attaher, Ali Salem, Muneer Alam

2025Agricultural Water Management15 citationsDOIOpen Access PDF

Abstract

Elevated CO2 (eCO2) significantly affect the carbon-water cycle in terrestrial ecosystems especially for gas exchange and water use efficiency (WUE). Therefore, in this study, we have conducted a meta-analysis to quantitative statistical means among studies and discuss how WUE responds to eCO 2 under pathway (C 3 and C 4 ), four enrichment methods and soil types based on 124 peer-reviewed studies and 1474 observations to provide an in-depth overview of how these factors interact under future CO₂ scenarios. Key findings reveal that: (1) C₃ crops, such as potato and tomato, show significantly greater increases in WUE compared to C₄ crops like maize, with effect sizes of 13.96 and 7.02 for plant-level WUE (WUEₚ), suggesting that C₃ crops may be more advantageous in water-limited environments due to reduced photorespiration under eCO₂; (2) soil type substantially modulates WUE responses, with clay soils, due to their high water-holding capacity, demonstrating the highest WUE enhancements (effect sizes of 7.87 for WUEₚ and 12.54 for yield WUE, WUEᵧ), while sandy soils, characterized by rapid drainage, showed limited improvements; and (3) greenhouse and growth chamber studies displayed the highest WUE improvements, while FACE experiments, which better replicate real-world conditions, indicated smaller WUE increases due to environmental variability, underscoring the need for a hybrid approach that merges controlled data with field insights to develop practical, water-efficient agricultural strategies. Collectively, these findings highlight the potential for crop- and soil-specific strategies to optimize WUE under elevated CO₂, offering valuable insights for sustainable agriculture and climate adaptation. • Potato and tomato (C3) show significantly greater increases in WUE compared to maize (C₄) crop. • soil type substantially modulates WUE responses, with clay soils. • greenhouse and growth chamber studies displayed the highest WUE improvements. • Low heterogeneity in FACE experiments, which better replicate real-world conditions.

Topics & Concepts

Environmental scienceWater-use efficiencyCropSoil typeSoil scienceAgronomyEnvironmental engineeringSoil waterIrrigationBiologyPlant responses to elevated CO2Plant Water Relations and Carbon DynamicsBioenergy crop production and management