A Simple Method to Design Irrigation Rate and Duration and Improve Water Use Efficiency

Water Resources Research

Kamai

Šimůnek

et al. 2020

Self Cite

The use of treated wastewater (WW) for irrigation is steadily increasing worldwide. However, irrigation with WW requires special attention as it may alter soil hydraulic properties and, eventually, affect crop yields. The main goal of this study was to investigate two approaches that could mitigate this adverse impact: (i) mixing WW with local freshwater (FW) and (ii) adjusting the irrigation management and design to the deteriorated soil hydraulic properties. Four water qualities resulting from mixing FW and WW at different ratios for irrigation of an avocado orchard planted on a clayey soil were considered: FW, M 1/3 (2/3 FW-1/3 WW), M 2/3 (1/3 FW-2/3 WW), and WW. Increasing the WW component in the irrigation water reduces the soil's saturated hydraulic conductivity and infiltrability, and this reduction is depth dependent. It also reduces the transpiration of trees and their trunk growth. This is supported by numerical simulations that showed that irrigation with WW produced the reduction in plant transpiration relative to irrigation with FW. Numerical simulations indicated that irrigation management and design could be adjusted to improve plant water uptake and reduce the differences due to water quality. The results indicate that decreasing the irrigation rate and increasing the wetted area per tree could increase the water uptake in WW-irrigated soils to almost equal that in FW-irrigated soils. This can be achieved by using drippers with lower discharge and by using more drippers per dripline, more driplines per tree, and more drippers per tree (concentric loops of driplines around each trunk).

Section: Resultssupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Mitigating the Impact of Irrigation With Effluent Water: Mixing With Freshwater and/or Adjusting Irrigation Management and Design

Water Resources Research

Kamai

Šimůnek

et al. 2020

Self Cite

“…For each soil, the information in q cap ( t ) can be used to estimate the ponding time that corresponds to each wetting rate (Figure 4c) (Assouline et al., 2007; Assouline, 2019). Similarly, e cap ( t ) can be used to estimate the duration of S1 for each soil and for each drying rate (Figure 4f).…”

Section: Resultsmentioning

confidence: 99%

Unique Relationship Between Rate and Cumulative Flow: A Property of Infiltration and Evaporation in Soils

Geophysical Research Letters

Kamai

2022

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Infiltration and evaporation are key components of the Earth hydrological cycle that depend on soil properties and climatic conditions. Here we show that, for both infiltration and evaporation, the water flow rate is a unique function of the cumulative flow in the soil. Hence, for a given soil, infiltration and evaporation curves corresponding to different wetting and drying rates are represented by one curve characterizing the capacity of the system for the relevant process. This insight reveals a natural and powerful property that shapes water interactions between soil and atmosphere. A quantitative expression of the evaporation capacity curve is proposed. A dimensionless representation of this model offers a simple tool to predict evaporation under natural soil and climatic conditions that vary in space and time. The infiltration and evaporation capacity models can be easily embedded in Earth System Models to estimate the hydrological response at various spatial and temporal scales.

“…The information is valuable as it presents the infiltration capacity curve characterizing each specific soil, and allows estimating runoff from any prescribed wetting rate (Assouline et al., 2007). It helps also in defining the respective wetting rates that prevent ponding and runoff formation, a key issue in the design of efficient irrigation (Assouline, 2019).…”

Section: Soil Hydrological and Agricultural Functionsmentioning

confidence: 99%

“…Information on the soil infiltration capacity, q cap , is valuable in terms of the hydrological response of soils. It is required to estimate ponding time; to evaluate runoff produced by a given wetting event (rainfall or irrigation); to reconstruct the infiltration curve for any given water application rate; and to prevent ponding during irrigation design (Assouline, 2019; Assouline et al., 2007; Brutsaert, 2005; Smith & Parlange, 1978). These are very important hydrological (natural rainfall) or agricultural (irrigation) elements of soil functioning.…”

Section: Soil Hydrological and Agricultural Functionsmentioning

confidence: 99%

What Can We Learn From the Water Retention Characteristic of a Soil Regarding Its Hydrological and Agricultural Functions? Review and Analysis of Actual Knowledge

Water Resources Research

2021

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The soil properties of the upper soil layer determine the partitioning between infiltration, runoff, and evaporation, key processes related to soil agricultural and hydrological functioning. It is therefore important to have some information on these soil functions based on available and easy‐to‐measure properties. This study presents what we can learn a‐priori from the soil water retention characteristic (WRC) on some important hydrological and agricultural functions. Based on a mathematical expression of the soil WRC, it is possible to estimate: the characteristic length, LC, related to the disruption of hydraulic continuity of the water liquid phase in the soil; the saturated hydraulic conductivity Ks; the unsaturated hydraulic conductivity function of water and air, K(θw) and K(θa); the saturation degree SeFC at field capacity and how long it will take to reach that state; the available water content in the soil, AWC; the capillary head at the wetting front, ψf; the infiltration capacity curve based on the Green and Ampt model, qcap(t); the time to ponding, tp, for any prescribed wetting rate; the cumulative water loss during stage‐1 evaporation; the duration of stage‐1 evaporation. All these a‐priori estimates are valuable and sometimes necessary for efficient design and planning in agricultural and hydrological applications. The values of these estimates depend upon the specific mathematical expression chosen to represent the WRC.