Regulated deficit irrigation: an effective way to solve the shortage of agricultural water for horticulture

Yang, Bo; Fu, Peining; Lu, Jiang; Ma, Fengwang; Sun, Xiangyu; Fang, Yulin

doi:10.1007/s44154-022-00050-5

Cited by 16 publications

(9 citation statements)

References 166 publications

(198 reference statements)

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“…This could be due to the fact that the water deficit was not severe, and the fruits grew due to the reserve carbohydrates stored in the stems and roots and were able to accumulate dry matter during periods of stress, as reported for pear [34] and for clementine by de Nules [35]. According to the theory of root-shoot balance, fruit trees under water stress transfer more nutrients to reproductive growth processes, and thus RDI can have a low negative effect on crop growth, especially on fruits, by saving water [5]. Taking into account these theories, we suggest that the 'Triunfo de Viena' pear not only possesses sufficient adaptive reserves but also a good ecological plasticity against hydric stress conditions in tropical highlands.…”

Section: Production Parametersmentioning

confidence: 82%

“…Regulated deficit irrigation (RDI) has been widely applied to fruit trees, such as grape, citrus, pear, apple, peach, cherry, blueberry and mango, as well as to melon [5]. In the RDI methodology, water stress is induced in the tree by irrigating less than the crop evapotranspiration (ETc) under standard conditions in certain phases of fruit development [6].…”

Section: Introductionmentioning

confidence: 99%

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Effect of Regulated Deficit Irrigation (RDI) on the Growth and Development of Pear Fruit (Pyrus communis L.), var. Triunfo de Viena

Vélez-Sánchez,

Casierra-Posada,

Fischer

2023

Sustainability

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The irrigation of crops represents 70% of the world’s water use. For crops grown in high-altitude tropical climates, due to the decrease in rainfall with increasing altitude, along with the effects of global warming, it is necessary to propose alternatives for sustainable fruit production with reduced water consumption. This study was carried out in Sesquilé, Colombia (South America), at an altitude of 2595 m a.s.l. for two successive years with pear trees, var. Triunfo de Viena. The objective of this work was to determine the effect of regulated deficit irrigation (RDI) on the absolute and relative growth rates of the equatorial diameter of the fruits, the fresh and dry weights, the number of fruits, the yield per tree and the water potential of the fruits. In 2014, during the rapid growth phase of the fruit, one group of plants was irrigated at 100% of the crop evapotranspiration (ETc) (control), another at 74% and a third group at 60%. In 2015, the three groups were irrigated at 100%, 48% and 27% of the ETc. The use of RDI did not significantly affect the growth of the fruits. This study showed that the ‘Triunfo de Viena’ pear tree not only has sufficient adaptive reserves, but also has good ecological plasticity under water stress conditions in high-altitude tropical climates. In cases where water is a limiting factor for pear tree production, RDI can obtain production rates similar to those of a regularly irrigated crop, as long as this technique is used and implemented in phenological states of low sensitivity to water stress without exceeding the tolerance limits of the plants to the stressor.

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Section: Production Parametersmentioning

confidence: 82%

Section: Introductionmentioning

confidence: 99%

Effect of Regulated Deficit Irrigation (RDI) on the Growth and Development of Pear Fruit (Pyrus communis L.), var. Triunfo de Viena

Vélez-Sánchez,

Casierra-Posada,

Fischer

2023

Sustainability

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“…Most of these techniques are expensive, time-consuming, or require specific machinery ( Iqbal et al., 2020 ). Regulated deficit irrigation is an optimization strategy that requires the crop to consciously tolerate a certain level of water deficit, sometimes resulting in decreased yield and significantly increased water use efficiency (WUE) ( Yang et al., 2022 ; Zou and Kang, 2022 ). Partial root-zone drying (PRD) is a modified version of deficit irrigation and has been used to improve WUE by controlling drought ( Jovanovic and Stikic, 2018 ).…”

Section: Introductionmentioning

confidence: 99%

Partial root-zone drying combined with nitrogen treatments mitigates drought responses in rice

Zhao,

Gao,

Kuang

et al. 2024

Front. Plant Sci.

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Drought is a major stress affecting rice yields. Combining partial root-zone drying (PRD) and different nitrogen fertilizers reduces the damage caused by water stress in rice. However, the underlying molecular mechanisms remain unclear. In this study, we combined treatments with PRD and ammonia:nitrate nitrogen at 0:100 (PRD0:100) and 50:50 (PRD50:50) ratios or PEG and nitrate nitrogen at 0:100 (PEG0:100) ratios in rice. Physiological, transcriptomic, and metabolomic analyses were performed on rice leaves to identify key genes involved in water stress tolerance under different nitrogen forms and PRD pretreatments. Our results indicated that, in contrast to PRD0:100, PRD50:50 elevated the superoxide dismutase activity in leaves to accelerate the scavenging of ROS accumulated by osmotic stress, attenuated the degree of membrane lipid peroxidation, stabilized photosynthesis, and elevated the relative water content of leaves to alleviate the drought-induced osmotic stress. Moreover, the alleviation ability was better under PRD50:50 treatment than under PRD0:100. Integrated transcriptome and metabolome analyses of PRD0:100 vs PRD50:50 revealed that the differences in PRD involvement in water stress tolerance under different nitrogen pretreatments were mainly in photosynthesis, oxidative stress, nitrogen metabolism process, phytohormone signaling, and biosynthesis of other secondary metabolites. Some key genes may play an important role in these pathways, including OsGRX4, OsNDPK2, OsGS1;1, OsNR1.2, OsSUS7, and YGL8. Thus, the osmotic stress tolerance mediated by PRD and nitrogen cotreatment is influenced by different nitrogen forms. Our results provide new insights into osmotic stress tolerance mediated by PRD and nitrogen cotreatment, demonstrate the essential role of nitrogen morphology in PRD-induced molecular regulation, and identify genes that contribute to further improving stress tolerance in rice.

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“…The subsurface drip irrigation approach (SSI) is becoming more common among agronomists since it enables the crop to be "spoon-fed" for water and nutrients, which are added directly to the plant's root zone (Wang et al, 2022;Yang et al, 2022). The SSI technique also greatly improves water use efficiency by reducing water waste from runoff, deep percolation, wind drift, and soil evaporation (Camp et al, 2000;Mati, 2011;Sheta and Fayed, 2021;Abdelbaset et al, 2023).…”

Section: Introduction Introduction Introduction Introductionmentioning

confidence: 99%

Integrating soil mulching and subsurface irrigation for optimizing deficit irrigation effectiveness as a water-rationing strategy in tomato production

ALKHATEEB,

ALI,

ABDOU

et al. 2024

Not Bot Horti Agrobo

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Irrigated agriculture from now on should be implemented under water scarcity. Hence, this research was designed to determine the optimal interaction between irrigation water-rationing strategy (deficit irrigation), irrigation techniques, and soil mulching to improve water use efficiency and maintaining plant performance as well as yield productivity of tomatoes. The experiment was set up during the 2020-2021 and 2021-2022 growing seasons. Three factors were studied: two drip irrigation techniques, surface (SI) and subsurface (SSI) irrigation, and two irrigation rates, 100% ETc for full irrigation (FI) and 60% ETc for deficit-irrigation (DI) along with three treatments of soil mulching, bare soil (BS), organic mulch (OrM) and black polyethylene mulch (BPE). The results demonstrated that applying the absolute regular DI regime significantly reduced vegetative growth, fruit yield, and yield component along with water productivity. Also, it reduced the physiological function measures, and nutrient content of the tomato leaf. Meanwhile, applying the DI regime via the SSI technique and integrated with BPE soil mulching proved the best optimization of the DI negative effect followed by applying the DI regime through either SSI or SI technique combined with OrM or BPE soil mulching, respectively. As a result, it is advisable to use the integration of DI via the SSI accompanied by BPE soil mulching since this is considered a good method for conserving irrigation water from being lost by both evaporation and seepage out of the root zone improving water use efficiency without significantly reducing tomato yield.

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Regulated deficit irrigation: an effective way to solve the shortage of agricultural water for horticulture

Cited by 16 publications

References 166 publications

Effect of Regulated Deficit Irrigation (RDI) on the Growth and Development of Pear Fruit (Pyrus communis L.), var. Triunfo de Viena

Effect of Regulated Deficit Irrigation (RDI) on the Growth and Development of Pear Fruit (Pyrus communis L.), var. Triunfo de Viena

Partial root-zone drying combined with nitrogen treatments mitigates drought responses in rice

Integrating soil mulching and subsurface irrigation for optimizing deficit irrigation effectiveness as a water-rationing strategy in tomato production

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