Lund University Publications

Evaluation of Modern Irrigation Techniques with Brackish Water

• Mark

Abstract

Modern irrigation techniques are becoming increasingly important in water-scarce countries especially in arid and semiarid regions. Higher crop production and better water use efficiency are usually achieved by drip irrigation as compared to other irrigation methods. Furthermore, by using drip irrigation simultaneously with brackish irrigation water, some of the water stress due to shortage of fresh water resources can be managed. The objective of the current study was to investigate the influence of geometric design, soil type, irrigation regime and amount, and salinity of irrigation water on soil water and salinity distribution as well as irrigation efficiency using drip irrigation techniques in Egypt and Tunisia. Field and laboratory... (More)

Modern irrigation techniques are becoming increasingly important in water-scarce countries especially in arid and semiarid regions. Higher crop production and better water use efficiency are usually achieved by drip irrigation as compared to other irrigation methods. Furthermore, by using drip irrigation simultaneously with brackish irrigation water, some of the water stress due to shortage of fresh water resources can be managed. The objective of the current study was to investigate the influence of geometric design, soil type, irrigation regime and amount, and salinity of irrigation water on soil water and salinity distribution as well as irrigation efficiency using drip irrigation techniques in Egypt and Tunisia. Field and laboratory experiments as well as numerical simulations were used to achieve these objectives. Two field experiments were conducted at two different sites and soil types in Tunisia. The first experiment was conducted to explore the effect of different drip irrigation treatment (i.e., surface drip irrigation with and without plastic mulch and subsurface drip irrigation) and regime (i.e., daily and bi-weekly) on soil water and salinity distribution as well as contaminant transport for sandy loam soil. The second experiment was carried out to investigate the mobility of different tracers (bromide and dye) under surface drip irrigation in loamy sand soil. Lab experiments using soil samples collected in Egypt and Tunisia were made to estimate soil hydraulic properties, soil texture, and soil moisture content. Numerical simulations for surface and subsurface drip irrigation and alternate partial root-zone surface and subsurface drip irrigation with brackish irrigation water were executed to investigate the effect of geometric design, irrigation regime and amount, and salinity of irrigation water on soil water and salinity distribution as well as irrigation efficiency for different soil types in El-Salam Canal project region, Egypt. Field experiments showed that maximum dye penetration depth during daily and bi-weekly irrigation occurred for subsurface drip irrigation. Also, during the bi-weekly irrigation, dye depth was not only larger but also occupied a larger soil volume than for the daily irrigation. Thus, bi-weekly irrigation increases the risk for groundwater contamination. Also, higher soil moisture content within the flow domain occurred with mulching treatment and daily irrigation. Simulations displayed a very close agreement with observed soil wetting. Multiple tracer experiments revealed that the bromide moved faster than dye. Therefore, fertilizers transport deeper than organic pollutants under surface drip irrigation in initially dry loamy sand soil. Numerical simulations verified this. On the other hand, numerical simulations for surface drip irrigation in El-Salam Canal cultivate land showed that soil hydraulic properties govern the shape of the wetted zone. The wetted depth was larger in sand while the wetted radius was lower as compared to loamy sand and sandy loam. Simulation results for subsurface drip irrigation (SDI) showed that deeper emitter depth increases the potential groundwater contamination risk and fertilizer leaching especially in sandy soil and shallow rooted plants. Also, it is preferable to control the wetted volume of any soil type by regulating the amount of irrigation water according to soil hydraulic properties. Simulation results also revealed that higher moisture content values within the flow domain and higher root water uptake rates occurred in case of short inter-plant emitter distances (IPED) under alternate partial root-zone surface and subsurface drip irrigation (APRDI and APRSDI, respectively). Therefore, Short IPED is preferable especially for root systems with limited lateral extension. Salinity results showed that as the salinity of irrigation water increased, the salinity levels at the soil surface at the location of the plant trunk under APRSDI increased. Therefore, APRSDI is more suitable with non-saline irrigation water, especially for shallow rooted plants. However, in case of using brackish irrigation water, short IPED and shallow emitter depth are recommended for reducing soil salinity below the plant trunk. (Less)

Abstract (Swedish)

Popular Abstract in English

Improving irrigation practices and optimal exploitation of available water resources are vital issues facing water scarcity and similar problems in arid and semiarid countries (e.g., Egypt and Tunisia). In these countries, the use of saline and low quality irrigation water (i.e., brackish irrigation water) is often associated by soil salinization risk and soil degradation due to mismanagement and improper irrigation methods. In the present study, field, laboratory, and numerical experiments were conducted. Field experiments were carried out in Tunisia to investigate soil water and salinity distribution under different treatments of drip irrigation (i.e., surface drip irrigation without and with... (More)

Popular Abstract in English

Improving irrigation practices and optimal exploitation of available water resources are vital issues facing water scarcity and similar problems in arid and semiarid countries (e.g., Egypt and Tunisia). In these countries, the use of saline and low quality irrigation water (i.e., brackish irrigation water) is often associated by soil salinization risk and soil degradation due to mismanagement and improper irrigation methods. In the present study, field, laboratory, and numerical experiments were conducted. Field experiments were carried out in Tunisia to investigate soil water and salinity distribution under different treatments of drip irrigation (i.e., surface drip irrigation without and with plastic mulch and subsurface drip irrigation surface) with two irrigation regimes (daily and bi-weekly) in a sandy loam soil. In addition, to explore the mobility of different tracers (i.e., dye and bromide) under surface drip irrigation in loamy sand soil as an indicator for the movement of fertilizers and organic pollutants through the field soil. Numerical simulations, on the other hand, were implemented to investigate the effect of geometric design aspects, irrigation regime and amount, and salinity of irrigation water on soil water and salinity distribution as well as irrigation efficiency for different soil types in the El-Salam Canal project region, Egypt under different drip irrigation techniques. These techniques were surface drip irrigation (DI), subsurface drip irrigation (SDI), alternate partial root-zone surface drip irrigation (APRDI), and alternate partial root-zone subsurface drip irrigation (APRSDI). Laboratory experiments were conducted for collected soil samples to provide required data for simulation implementation and analysis.

Field results showed that mulching treatment with daily irrigation regime reduces groundwater contamination risk and improves soil water status within the soil domain in sandy loam soil over other drip irrigation treatments and regimes. In addition, the bromide flow faster as compared to dye. Therefore, fertilizers can move deeper than organic pollutants under surface drip irrigation. On the other hand, numerical simulations for El-Salam Canal cultivated land showed that under DI soil hydraulic properties should be considered during designing the drip system. Simulation results for SDI showed that shallow emitter depth is recommended in regions with shallow groundwater to reduce groundwater contamination risk and fertilizer leaching. In addition, it is preferable to control the wetted volume of any soil type by regulating the amount of irrigation water according to soil hydraulic properties. Simulation results also demonstrated that short inter-plant emitter distances (IPED) is appropriate to sustain a considerable amount of soil moisture in the zone of maximum root density under APRDI and APRSDI. Thereby, higher root water uptake rates were recorded with short IPED. Thus short IPED is preferable especially for root system with limited lateral extension. Salinity results showed that APRSDI is more suitable with non-saline irrigation water, especially for shallow rooted plants. However, short IPED and shallow emitter depth are recommended for reducing soil salinity below the plant trunk in case of using brackish irrigation water. Based on the above, HYDRUS-2D/3D can be used as a fast and cost effective assessment tool for water flow and salt movement under different treatments and techniques of drip irrigation. (Less)