Effect of drip and furrow irrigation at different irrigation levels on water use efficiency and economics of maize (Zea Mays L.) at Werer, Middle Awash, Ethiopia

Borena, Fikadu Robi; Seyoum, Teshome

doi:10.5897/ajar2021.15653

Cited by 4 publications

(5 citation statements)

References 11 publications

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“…Irrigation water productivity (IWP) is the yield produced per unit of irrigation water use [70]. It is a comprehensive indicator that reveals the level of irrigation and crop management [33,68]. IWP is estimated as:…”

Section: Crop Water Productivity and Irrigation Water Productivitymentioning

confidence: 99%

“…Field experiments help to examine crops' response in terms of yield and crop water productivity in real-world settings [32,33]. However, they are time-consuming, expensive, and difficult to maintain over extended periods of time such as for climate change studies.…”

Section: Introductionmentioning

confidence: 99%

“…Instead, process-based crop models can be considered. Crop models simulate the effects of irrigation management techniques under longterm interannual climatic variability that includes a future climate change [3,32,33,[35][36][37][38]. Process-based simulation models that incorporate current and future climatic conditions, such as CO 2 concentration, temperature, and rainfall variations generated by global climate models (GCMs), have been widely used for crop production and assessments [35,36].…”

Section: Introductionmentioning

confidence: 99%

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Response of Winter Wheat Production to Climate Change in Ziway Lake Basin

et al. 2022

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The crop production and limited freshwater resources in the Central Rift Valley (CRV) Lake Basin of Ethiopia have been facing pressure from warmer and drier climates. Thus, irrigation with the goal of increasing water use efficiency and the productivity of rainfed agriculture is vital to address climate effects, water scarcity, and food security. This study is aimed at assessing the sustainability of winter wheat production under climate change, and irrigation as an adaptation measure to improve yield, crop water productivity (CWP), and irrigation water productivity (IWP) in the CRV of Ethiopia. AquaCrop is applied to evaluate the effects of climate change and simulate irrigation as an adaptation measure. The analysis covers the baseline (1981–2020) and future (2026–2095) periods with each period categorized into three rainfall years (wet, normal, and dry). The future period is described using two representatives’ concentration pathways (RCP4.5 and PCP8.5) scenarios. The results under rainfed and future climate conditions show that the winter wheat yield and CWP are projected to be lowered as compared to the baseline period. Most importantly, a significant reduction in wheat yield and CWP is noticed during the dry years (−60% and −80%) compared to the wet years (−30% and −51%) and normal years (−18% and −30%), respectively. As compared to rainfed agriculture, irrigation significantly reduces the risk of wheat yield decline and improves the CWP. Irrigation is also able to improve the CWP of rainfed wheat production ranging from 0.98–1.4 kg/m3 to 1.48–1.56 kg/m3. A projected CWP improvement of 1.1–1.32 kg/m3 under irrigation is possible from 0.87–1.1 kg/m3 under rainfed conditions. The study concludes that optimizing irrigation as a climate-change-adapting strategy in the CRV has a more pronounced positive impact to the rainfed production system, especially for the dry and normal years.

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Section: Crop Water Productivity and Irrigation Water Productivitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Response of Winter Wheat Production to Climate Change in Ziway Lake Basin

et al. 2022

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“…Therefore, now, the major focus is to maximize water productivity through microirrigation (Ali & Talukder, 2008; Dar et al, 2017; Fumagalli et al, 2014; Kumari et al, 2014). In maize, surface drip irrigation is considered a viable option for efficient irrigation management, saving 20% of irrigation water (Kaur, 2013) compared to the conventional practice of flooding without any yield penalty. However, the adoption of surface drip irrigation remains a challenge as laterals interfere with cultivation practices.…”

Section: Introductionmentioning

confidence: 99%

“…The CERES‐Maize model in the framework of the Decision Support System for Agrotechnology Transfer (DSSAT) (Jones et al, 2003) has been used to optimize irrigation and nitrogen management in maize (Jiang et al, 2016; Kaur & Arora, 2018; Panda et al, 2004). Most of these studies on modelling the combined effect of irrigation and nitrogen management on the water balance components and water productivity of spring maize in Punjab were conducted under conventional furrow irrigation (Kaur & Arora, 2019) systems and surface drip irrigation (Kaur, 2013). However, under SDI systems, information on modelling the combined effects of the amount and frequency of nitrogen and irrigation on the water productivity and water balance components of spring maize is limited.…”

Section: Introductionmentioning

confidence: 99%

Interactive effect of nitrogen and irrigation on evapotranspiration, growth, yield and water productivity of subsurface drip‐irrigated spring maize: Field and simulation studies

Kaur

Singh

Brar

et al. 2023

Irrigation and Drainage

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In northwest India, spring maize water productivity can be increased with subsurface drip irrigation. Therefore, a field experiment was conducted in a split-plot design for 2 years to assess the effect of three nitrogen levels (125 [N 1 ], 100 [N 2 ] and 75 [N 3 ] kg N ha À1 ) in the main plots and seven irrigation regimes (six subsurface and one surface drip) in the subplots on water productivity of spring maize. Subsurface drip irrigation was applied at 100%, 80% and 60% cumulative pan evaporation on alternate days (I 1 , I 3 and I 5 ) and at 2-day intervals (I 2 , I 4 and I 6 ) along with surface drip irrigation at 80% pan evaporation on alternate days (I 7 ). The evapotranspiration (ET), transpiration (T), dry matter accumulation (DMA), leaf area index (LAI), root mass density (RMD), N uptake and grain yield were at par in N 1 and N 2 but significantly higher than in N 3 . T, DMA, LAI, RMD, grain N uptake and grain yield were at par in I 1 , I 2 , I 3 and I 7 but significantly higher than in I 4 , I 5 and I 6 . The real water productivity was at par in N 1 I 1 , N 1 I 3 and N 2 I 3 but significantly higher than other interactive combinations. The CERES-Maize model satisfactorily simulated crop biomass, grain yield, LAI, ET and transpiration.

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Modern Drip Irrigation Technology on Tomato and Head Cabbage Production and Its Economic Feasibility at Misrak Silti District, Siltie Zone, Ethiopia

Abebo,

Bekele,

Wabela

et al. 2024

WJFST

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In Ethiopia various techniques were applied to improve on-farm irrigation water management under surface irrigation, especially on furrow irrigation system for last many years, however, it was very difficult to achieve threshold limit of water use efficiency, wisely use of scarce water resources in irrigated field, crop water productivity, precisely controlled application of irrigation water to plant roots, uniform water delivery to all plants, crop yield and its quality, regulate flow, deliver optimum crop water requirement, field water losses, groundwater withdrawal and save labor. It is great practical significance and series of measures using drip irrigation system to solve mentioned problems in irrigated field, because the irrigated agriculture is largest water-consuming sector in this area. This study was aimed to demonstrate drip irrigation technology, prove its economic feasibility and create skills of farmers and extension experts on implementation of the drip system on tomato (Galila 555) and head cabbage (Copen Hagen) productions within groundwater source area on Balo koriso main station in Misrak Silti woreda, Siltie zone, southern Ethiopia. The activity was done for four consecutive years (2019 to 2022 G. C) on fixed plot of 2500 square meter area in collaboration with Agricultural Research Institute and Techno serve project. During demonstration all the costs were considered to economic feasibility including initial investment cost. The study found that the use of drip irrigation saved 3690 m<sup>3</sup>/ha of water compared with use of furrow irrigation. This saved water may irrigate additional 2ha area of land by drip irrigation. This study also revealed that, a net income of 313066.04 ETB/ha in single irrigation season was obtained using modern drip irrigation technology. The farmers and local experts recognized noticeable saving water, fuel cost, irrigating time and labour, good crop performance from demonstrated drip irrigation system and shown interest to use the technology abundantly. Therefore, scaling up locally manageable drip irrigation system around the study area through comprehensive training of farmers and supportive staffs and allowing sufficient local market for drip kits and incentives or loan will be economically feasible and affordable to increase income and saves irrigation water.

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Effect of drip and furrow irrigation at different irrigation levels on water use efficiency and economics of maize (Zea Mays L.) at Werer, Middle Awash, Ethiopia

Cited by 4 publications

References 11 publications

Response of Winter Wheat Production to Climate Change in Ziway Lake Basin

Response of Winter Wheat Production to Climate Change in Ziway Lake Basin

Interactive effect of nitrogen and irrigation on evapotranspiration, growth, yield and water productivity of subsurface drip‐irrigated spring maize: Field and simulation studies

Modern Drip Irrigation Technology on Tomato and Head Cabbage Production and Its Economic Feasibility at Misrak Silti District, Siltie Zone, Ethiopia

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