Abstract
Water saving techniques such as drip irrigation are important for rice (Oriza sativa L.) production in some areas. Subsurface drip irrigation (SDI) is a promising alternative for intensive cropping since surface drip irrigation (DI) requires a higher degree of labor to allow the use of machinery. However, the semi-aquatic nature of rice plants and their shallow root system could pose some limitations. A major design issue when using SDI is to select the dripline depth to create appropriate root wetting patterns as well as to reduce water losses by deep drainage and evaporation. Soil texture can greatly affect soil water dynamics and, consequently, optimal dripline depth and irrigation frequency needs. Since water balance components as deep percolation are difficult to estimate under field conditions, soil water models as HYDRUS-2D can be used for this purpose. In the present study, we performed a field experiment using SDI for rice production with Onice variety. Simulations using HYDRUS-2D software successfully validated soil water distribution and, therefore, were used to predict soil water contents, deep drainage, and plant water extraction for two different dripline depths, three soil textures, and three irrigation frequencies. Results of the simulations show that dripline depth of 0.15 m combined with one or two daily irrigation events maximized water extraction and reduced percolation. Moreover, simulations with HYDRUS-2D could be useful to determine the most appropriate location of soil water probes to efficiently manage the SDI in rice.
Highlights
Rice is a main international crops and is a staple food in many countries
From day 15 to 70 DAS, the plot was watered in order to maintain the soil water content in sensor 2 (Figure 1) at 0.257 m3 m−3, corresponding to a matric potential of −10 kPa, resulting in cumulative applied irrigation water was lower than cumulative crop section
The root of the mean square error (RMSE) and R2 values obtained by comparing the water contents measured in the field and simulated with HYDRUS-2D showed a reasonably good prediction with the latter, indicating that numerical simulations can be: (1) a useful tool to optimize the design and management of Subsurface drip irrigation (SDI) taking into account the hydraulic properties of soils, as well as, (2) predicting water percolation
Summary
Rice is a main international crops and is a staple food in many countries. 90% of worldwide rice production takes place in Asia. In 2018, 67% of the world’s total rice production came from China, India, Indonesia, and Bangladesh [1]. In Europe, Spain is the second largest producer after. With a total surface area of 105,422 ha in 2019 [2]. About 75% of rice is produced under continuous flooded irrigation and uses 34 to 43% of the world’s irrigation water [3]. The total average water use in continuously flooded irrigation can greatly vary depending on the soil type, rice culture, and water management practices, ranging from
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