Standardization of Alternate Wetting and Drying (AWD) Method of Water Management in Lowland Rice (<i>ORYZA Sativa</i>L.) for Upscaling in Command Outlets

Mote, Kishor; Rao, V. Praveen; Ramulu, V.; Kumar, Krishna; Devi, M. Uma

doi:10.1002/ird.2179

Cited by 16 publications

(11 citation statements)

References 37 publications

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“…The logic of the information transmission process is presented in the flowchart of Figure 6 , including the data collected by the farmer, and automatic sensors, to the irrigation management decision, articulated with the water supply conditions at district level [ 7 , 51 , 52 ].…”

Section: Resultsmentioning

confidence: 99%

“…Therefore, the use of soil moisture, or soil water potential sensors to control the crop water stress during the drying phase is an important issue [ 57 ]. These different methods can be articulated with sensing mechanisms aimed at automating irrigation [ 36 , 52 ], to optimize water consumption and crop productivity, and reduce the additional manpower required by the AWD. This topic represents an important and current area of investigation, which deserves the best attention [ 58 ].…”

Section: Discussionmentioning

confidence: 99%

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Alternate Wetting and Drying in the Center of Portugal: Effects on Water and Rice Productivity and Contribution to Development

Gonçalves

Nunes

Ferreira

et al. 2022

Sensors

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Rice irrigation by continuous flooding is highly water demanding in comparison with most methods applied in the irrigation of other crops, due to a significant deep percolation and surface drainage of paddies. The pollution of water resources and methane emissions are other environmental problems of rice agroecosystems, which require effective agronomic changes to safeguard its sustainable production. To contribute to this solution, an experimental study of alternate wetting and drying flooding (AWD) was carried out in the Center of Portugal in farmer’s paddies, using the methodology of field irrigation evaluation. The AWD results showed that there is a relevant potential to save about 10% of irrigation water with a reduced yield impact, allowing an additional period of about 10 to 29 days of dry soil. The guidelines to promote the on-farm scale AWD automation were outlined, integrating multiple data sources, to get a safe control of soil water and crop productivity. The conclusions point out the advantages of a significant change in the irrigation procedures, the use of water level sensors to assess the right irrigation scheduling to manage the soil deficit and the mild crop stress during the dry periods, and the development of paddy irrigation supplies, to allow a safe and smart AWD.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Alternate Wetting and Drying in the Center of Portugal: Effects on Water and Rice Productivity and Contribution to Development

Gonçalves

Nunes

Ferreira

et al. 2022

Sensors

View full text Add to dashboard Cite

show abstract

“…Although the agronomic effects of AWD vary with the duration and severity of soil drying, mild soil water deficits decreased water use by 23% while yields were statistically similar to continuously flooded crops, especially if AWD was applied either during the vegetative growth phase or reproductive growth phase, but not both (Carrijo et al, 2017). Nevertheless, this meta-analysis conceals considerable variation in the agronomic responses at specific sites, such that AWD sometimes significantly increases crop yields even though less water was applied (Mote et al, 2017;Norton et al, 2017a;Song et al, 2019). More detailed measurements of crop physiology are required to understand how AWD improves yield, but mechanisms may include leaf angle changes that allow greater light penetration of the canopy thereby boosting photosynthesis (Price et al, 2013), increasing the proportion of productive tillers (Howell et al, 2015;Mote et al, 2017;Norton et al, 2017a;Yang et al, 2017) and other grain yield components (Rahman and Bulbul, 2014;Li et al, 2018a;Song et al, 2019).…”

Section: Introductionmentioning

confidence: 89%

“…Nevertheless, this meta-analysis conceals considerable variation in the agronomic responses at specific sites, such that AWD sometimes significantly increases crop yields even though less water was applied (Mote et al, 2017;Norton et al, 2017a;Song et al, 2019). More detailed measurements of crop physiology are required to understand how AWD improves yield, but mechanisms may include leaf angle changes that allow greater light penetration of the canopy thereby boosting photosynthesis (Price et al, 2013), increasing the proportion of productive tillers (Howell et al, 2015;Mote et al, 2017;Norton et al, 2017a;Yang et al, 2017) and other grain yield components (Rahman and Bulbul, 2014;Li et al, 2018a;Song et al, 2019). AWD can be applied during grain filling to stimulate the remobilisation of stem carbohydrates that can contribute up to 40% of grain mass accumulation (Yang and Zhang 2010).…”

Section: Introductionmentioning

confidence: 99%

Alternate wetting and drying irrigation increases water and phosphorus use efficiency independent of substrate phosphorus status of vegetative rice plants

Acosta‐Motos

Rothwell

Massam

et al. 2020

Plant Physiology and Biochemistry

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“…This water level still allows the roots of the rice plant to continue capturing water from the saturated soil, therefore, will not cause the yield to decline [29]. The practice of AWD can save irrigation water up to 30% without a decline in yield [1,4,15,25,35,37,45,51,55,57,61,62,66,67,69]. It also reduces irrigation hours by about 38% [47] and lowers methane emissions by as much as 50% [12,51,42].…”

Section: Introductionmentioning

confidence: 99%

Performance evaluation of a water level sensor under various turbidity levels in lowland crop production systems

Pereira

Ramirez

Agulto

et al. 2022

IOP Conf. Ser.: Earth Environ. Sci.

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The practice of alternate wetting and drying (AWD), a water-saving technology in lowland crop production systems, can be greatly facilitated using wireless water level sensors. However, these sensors generally work under clear water conditions. The sensitivity of these sensors to turbidity is important for accurate water level measurement and appropriate irrigation scheduling. This study evaluated the performance of a high-end water level sensor of the submersible pressure transducer type under various turbidity levels. The performance tests were performed in the laboratory using water samples collected from a typical lowland rice production system under various levels of turbidity replicated three times with clear water as control. The readings of the sensors were compared with manual readings for each turbidity level in all replications. Results showed that the measured water level depth generally increases with increasing turbidity for each voltage level. The linear regression or calibration equation developed for each turbidity level proved to be adequate as evidenced by a relatively low RMSE of less than 1 mV. Results of ANOVA suggest that turbidity significantly affects the accuracy of the water level sensor (p <.001). A unified calibration equation (R2=0.9985 and RMSE=1.971 mV) was developed to account for the effect of turbidity up to 4300 FAU on the water level measurements. Results of this study can be used to improve the accuracy of water level monitoring in irrigated lowland crop production systems employing alternate wetting and drying technology to further increase irrigation efficiencies and augment water savings particularly during the dry season or under water-scarce conditions for a more sustainable crop production.

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Standardization of Alternate Wetting and Drying (AWD) Method of Water Management in Lowland Rice (ORYZA SativaL.) for Upscaling in Command Outlets

Cited by 16 publications

References 37 publications

Alternate Wetting and Drying in the Center of Portugal: Effects on Water and Rice Productivity and Contribution to Development

Alternate Wetting and Drying in the Center of Portugal: Effects on Water and Rice Productivity and Contribution to Development

Alternate wetting and drying irrigation increases water and phosphorus use efficiency independent of substrate phosphorus status of vegetative rice plants

Performance evaluation of a water level sensor under various turbidity levels in lowland crop production systems

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