Irrigation Strategies With Water Deficit in ‘Tommy Atkins’ Mango Tree

Santos, Marcelo Rocha dos; Donato, Sérgio Luíz Rodrigues; Faria, Leandro Neves; Coelho, E. F.; Cotrim, Paulo Roberto Fernandes

doi:10.1590/1809-4430-eng.agric.v36n6p1096-1109/2016

Cited by 6 publications

(6 citation statements)

References 15 publications

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“…O método da RDI tem sido avaliado em mangueira (SANTOS et al, 2016b;COTRIM et al, 2017) como em várias outras culturas; mas ainda não foi avaliado em bananeira, que é de maior consumo de água. O emprego do método exige o conhecimento das fases fenológicas da cultura e particularmente das fases fenológicas de maior e menor demanda de água pelas plantas.…”

Section: Introductionunclassified

Irrigação Com Deficit Da Bananeira Cultivar BRS Platina Em Condições Semiáridas

Coelho¹,

Silva²,

Barros³

et al. 2019

Agrarian

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Section: Introductionunclassified

Irrigação Com Deficit Da Bananeira Cultivar BRS Platina Em Condições Semiáridas

Coelho¹,

Silva²,

Barros³

et al. 2019

Agrarian

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“…In recent years, the related research on RDI had been gradually increased and enriched, and it had been tested or applied in a variety of crops. Such as citrus (Gonzalez-Dugo et al 2018 ; Romero-Trigueros et al 2017 , 2020 ), grape (da Silva et al 2018 ; Guo et al 2021 ; Ju et al 2019 ), blueberry (Keen and Slavich 2012 ; Lobos et al 2016 ), pear (Lepaja et al 2018 ; Wu et al 2020 ), mango (Dos Santos et al 2016 , 2020 ), peach (Falagan et al 2016 ; Manuel Miras-Avalos et al 2016 , 2017 ), melon (Lamaoui et al 2018 ; Zeinalipour et al 2017 ) and other fruits, as well as tomato (Bogale et al 2016 ; Coyago-Cruz et al 2019 ; Hooshmand et al 2019 ; Wang and Zhang 2014 ), lettuce (Chang et al 2021 ; Lin et al 2020 ), sugar beet (Abyaneh et al 2017 ; Li et al 2019 ), cauliflower (Abdelkhalik et al 2019a ; Hachmann et al 2019 ), pepper (Abdelkhalik et al 2020 ; Yang et al 2018 ), potato (Xie et al 2012 ) and other vegetables. Some food crops such as wheat (El-Sanatawy and Zedan 2020 ; Ma et al 2019 ; Zhang et al 2021 ), maize (Ma et al 2016 ; Salem et al 2021 ) and horticultural flowers such as marigold flower (Yasheshwar et al 2017 ) also had related studies on the application of RDI.…”

Section: Definition and Main Approaches Of Rdimentioning

confidence: 99%

Regulated deficit irrigation: an effective way to solve the shortage of agricultural water for horticulture

Yang

et al. 2022

Stress Biology

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The deficient agricultural water caused by water shortage is a crucial limiting factor of horticultural production. Among many agricultural water-saving technologies, regulated deficit irrigation (RDI) has been proven to be one of the effective technologies to improve water use efficiency and reduce water waste on the premise of maintaining the quality of agricultural products. RDI was first reported more than 40 years ago, although it has been applied in some areas, little is known about understanding of the implementation method, scope of application and detailed mechanism of RDI, resulting in the failure to achieve the effect that RDI should have. This review refers to the research on RDI in different crops published in recent years, summarizes the definition, equipment condition, function, theory illumination, plant response and application in different crops of RDI, and looks forward to its prospect. We expect that this review will provide valuable guidance for researchers and producers concerned, and support the promotion of RDI in more horticultural crops.

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“…In this way, nutrients and photoassimilates are targeted for reproductive development. However, more severe deficits compromise the photosynthetic rate (Santos et al, 2016), causing a significant reduction in yield, as observed in the PRD with the application of 40% ETc.…”

Section: Yield and Water Use Efficiency Of 'Palmer' Mangomentioning

confidence: 99%

“…In the mango crop, the RDI and PRD strategies have been investigated (Spreer et al, 2007;Spreer, Ongprasert, Hegele, Wunsche, & Muller, 2009), Srikasetsarakul et al (2015); Santos, Donato, Faria, Coelho and Cotrim (2016) and shown results that indicate water and energy savings, improved fruit quality and maintenance of yield.…”

Section: Introductionmentioning

confidence: 99%

Yield and water use efficiency in 'Tommy Atkins' and 'Palmer' mango trees under localized irrigation with water deficit

Santos

Cotrim

Mesquita

et al. 2020

Semina: Ciênc. Agrár.

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The increasing water demand of crops in response to climate change; the prospect of expanded irrigated areas; the population growth; and competition with multiple uses of water affect the availability of water resources for agriculture. Thus, measures are required that involve the adoption of irrigation-management strategies able to increase water savings without compromising crop yield, especially in semi-arid conditions, where water resources are limited, and in large-scale commercial cultivation such as in 'Tommy Atkins' and 'Palmer' mango, the second most widely grown irrigated fruit crop. The objective of this study was to examine the influence of irrigation systems (drip and micro-sprinkler) and deficit-irrigation strategies on the yield and water use efficiency (WUE) of 'Tommy Atkins' and 'Palmer' mango trees. The study was developed through two experiments conducted in the Irrigated Perimeter of Ceraíma, located in municipality of Guanambi - BA, Brazil. Two trials were carried out in a completely randomized design. For the 'Tommy Atkins' cultivar, 12 strategies were tested, involving regulated deficit irrigation (RDI) by micro-sprinkler irrigation and partial rootzone drying (PRD) by drip, in three production cycles. For ‘Palmer’ mango, 10 irrigation strategies were evaluated under the same previously described conditions, in only one production cycle. The reduction in water application in RDI was 25 and 50% of the crop evapotranspiration (ETc); and, in PRD, 20, 40 and 60% ETc. ‘Tommy Atkins’ mango achieved higher yields under micro-sprinkler irrigation with full irrigation and in the strategies involving the application of 50 and 75% ETc in stages II and III. These two strategies also provided greater WUE, along with PRD40. Water use efficiency was lower in the third evaluation cycle when compared with the first. ‘Palmer’ mango showed higher yields and WUE under drip irrigation, with the best yields achieved with full irrigation and in the strategies of PRD100, 80%, 60% and RDI with 50% ETc in stage III. The best WUE was obtained in PRD with 60 and 40% ETc.

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Irrigation Strategies With Water Deficit in ‘Tommy Atkins’ Mango Tree

Cited by 6 publications

References 15 publications

Irrigação Com Deficit Da Bananeira Cultivar BRS Platina Em Condições Semiáridas

Irrigação Com Deficit Da Bananeira Cultivar BRS Platina Em Condições Semiáridas

Regulated deficit irrigation: an effective way to solve the shortage of agricultural water for horticulture

Yield and water use efficiency in 'Tommy Atkins' and 'Palmer' mango trees under localized irrigation with water deficit

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