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Response of rice's hydraulic transport and photosynthetic capacity to drought-flood abrupt alternation

Yong Liu, Tiesong Hu, Rui Zhu, Huandi Li, Qiuwen Chen, Peiran Jing, Ali Mahmoud, Yanxuan Wang, Xiang Li

2024Agricultural Water Management11 citationsDOIOpen Access PDF

Abstract

Knowledge of the potential interactive effects of drought and flooding on the maximum carboxylation rate at 25°C ( V max25 ) and maximum hydraulic conductance ( K max ) is essential for the precise modeling of crop growth, water-carbon cycling, and crop yield formation. However, the lack of data on drought–flood abrupt alternation (DF) experiments and appropriate models to calibrate parameters without the need to specify photosynthetic and hydraulic transport capacity a priori make it difficult to further our understanding of the potential interaction effects on V max25 and K max . Hence, this study aimed to investigate the potential effects of interactions between the preceding drought and the subsequent flooding on V max25 and K max . We propose a nested optimization model for calibrating photosynthetic and hydraulic conductance capacity while simultaneously modeling carbon assimilation rate and stomatal conductance. A two-year DF experiment for rice from 2017 to 2018 was conducted to validate the new framework at the Key Laboratory of Water Resources and Hydropower of Anhui Province, Bengbu, China. The results show that reasonable K max and V max25 from gas exchange data can be extracted with the proposed nested model framework. We find two distinct interactions between the prior drought and the subsequent flooding on V max25 and K max : (1) the antagonistic effect of the preceding mild drought on the subsequent-flood-induced reduction of hydraulic transport and photosynthetic capacity, and (2) the synergistic effect of the subsequent flooding on the preceding drought-induced reduction in hydraulic transport and photosynthetic capacity. Revealing the interaction of drought and flooding on K max and V max25 of rice under DF events helps to understand rice’s response to compound water stress on multiple timescales and the stomatal and non-stomatal co-limitations, and these findings can be used as valuable guidelines for accurately predicting the impact of future extreme weather events on agricultural production. • A bilevel optimization framework coupling stomatal and hydraulic regulation is proposed to calculate K max . • Two years of experiments revealed the interaction between preceding drought and subsequent flooding on K max and V max25 . • Mild drought in drought–flood abrupt alternation (DF) antagonized the damage to K max and V max25 caused by flooding. • Moderate and severe preceding drought exacerbated the damage to rice K max and V max25 caused by subsequent flooding in DF. • Subsequent flooding in DF synergistically impaired K max and V max25 of preceding drought rice.

Topics & Concepts

Flood mythEnvironmental scienceAlternation (linguistics)Hydrology (agriculture)PhotosynthesisPhotosynthetic capacityFlooding (psychology)GeologyGeotechnical engineeringGeographyBotanyBiologyLinguisticsPhilosophyArchaeologyPsychologyPsychotherapistPlant responses to water stressRice Cultivation and Yield ImprovementPlant Water Relations and Carbon Dynamics