Deficit Irrigation to Control Vegetative Growth in Apple and Monitoring Fruit Growth to Schedule Irrigation

Ebel, Robert C.; Proebsting, E. L.; Evans, Robert G.

doi:10.21273/hortsci.30.6.1229

Cited by 75 publications

(41 citation statements)

References 11 publications

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“…Moreover, Laurie and Magoro [25] also reported that reduction in vine length of sweet potato has been positively correlated to the decline in irrigation rates from 100% full irrigation to 30% irrigation. Similar to the present study, Ebel et al [26] found that an extended irrigation interval led to decrease in percentage of vine length in sweet potato. Branch number was also found to be significantly reduced when extended irrigation interval was considered.…”

Section: Vine Length Leaf Number Branch Number and Internode Lengthsupporting

confidence: 91%

Morpho-physiological and Yield Responses of Sweet Potato (Ipomoea batatas (L.) Lam.) Genotypes to Frequency of Irrigation under Greenhouse Condition

Roro

Tesfaye

2019

IJPSS

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Introduction:The sweet potato (Ipomoea batatas Lam.), is one of the root and tuber crops grown from low land to high land region of Ethiopia. However, its productivity depends on adaptability and tolerance to different environmental stresses and the capacity of the crop to enhance water use efficiency under moisture stress conditions. The objective of this study was to evaluate impact of irrigation interval on morpho-physiological characteristics of sweet potato varieties. Methodology: The trial was a 3 x 2 factorial arrangement in CRD design consisting: three irrigation intervals (daily-control), four days and seven days interval) combined with two sweet potato genotypes (Hawassa-83 and Kulfo) with three replications. Results: The morpho-physiological indicators, morphological traits, water use efficiency (WUE), Relative leaf water content (RLWC), leaf gas exchange, stomata density, and tuber yield were evaluated. The result indicated that morphological traits were significantly (P≤0.05) responded to genotype and irrigation frequencies. As compared to daily irrigation, an extended watering interval Original Research Article2 to seven days irrigation interval significantly reduced leaf number, vine length, branch number and internode length by 55.42, 19.83 cm, 2.17 and 0.35 cm, respectively. Stomata density was strongly responded to genotypes than effect of irrigation frequency. Genotype Hawassa-83 had approximately 2.0 more stomata per mm 2 than genotype Kulfo regardless to irrigation frequency. The interaction effect between genotype and irrigation frequency revealed significant influence on photosynthesis and transpiration rate. The rate of assimilate accumulation was significantly reduced (by 9.97 mol m -2 s -1 ) in Hawassa-83 irrigated due to extended irrigation interval to seven days than variety irrigated daily. Delay irrigation for four and seven days reduced transpiration rate in genotype Hawassa-83 by 0.74 mmol m -2 s -1 and 0.84 mmol m -2 s -1, respectively. Result on WUE indicated that Kulfo was found better in efficiently utilizing water under extended irrigation interval than Hawassa-83. The leaf water content was significantly (P ≤ 0.001) responded to irrigation frequency than genotypes. The higher leaf relative water content was obtained from daily irrigation than extended irrigation interval.

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Section: Vine Length Leaf Number Branch Number and Internode Lengthsupporting

confidence: 91%

Morpho-physiological and Yield Responses of Sweet Potato (Ipomoea batatas (L.) Lam.) Genotypes to Frequency of Irrigation under Greenhouse Condition

Roro

Tesfaye

2019

IJPSS

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“…These management strategies are taking advantage of physiological responses of certain crops to drought stresses that result in a reduction in vegetative production in favor of fruit yield. Research has shown beneficial responses in Australia on peaches [ Chalmers et al , 1981] and pears [ Mitchell et al , 1984]; and in Washington on apples [ Proebsting et al , 1977; Middleton et al , 1981; Peretz et al , 1984; Evans et al , 1993, Ebel et al , 1995; Drake and Evans , 1997], citrus [ Goldhamer and Salinas , 2000], grapes [ Evans et al , 1990; Dry and Loveys , 1998; McCarthy et al , 2000], and other crops. These results have shown that carefully managing the severity and duration of a uniform, constant level of water stress on vigorous perennial crops can be advantageous to crop quality, depending somewhat on rootstocks and varieties.…”

Section: Options For Improving the Productivity Of Watermentioning

confidence: 99%

Methods and technologies to improve efficiency of water use

Evans

Sadler²

2008

Water Resources Research

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342

189

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The competition for existing freshwater supplies will require a paradigmatic shift from maximizing productivity per unit of land area to maximizing productivity per unit of water consumed. This shift will, in turn, demand broad systems approaches that physically and biologically optimize irrigation relative to water delivery and application schemes, rainfall, critical growth stages, soil fertility, location, and weather. Water can be conserved at a watershed or regional level for other uses only if evaporation, transpiration, or both are reduced and unrecoverable losses to unusable sinks are minimized (e.g., salty groundwater or oceans). Agricultural advances will include implementation of crop location strategies, conversion to crops with higher economic value or productivity per unit of water consumed, and adoption of alternate drought‐tolerant crops. Emerging computerized GPS‐based precision irrigation technologies for self‐propelled sprinklers and microirrigation systems will enable growers to apply water and agrochemicals more precisely and site specifically to match soil and plant status and needs as provided by wireless sensor networks. Agriculturalists will need to exercise flexibility in managing the rate, frequency, and duration of water supplies to successfully allocate limited water and other inputs to crops. The most effective means to conserve water appears to be through carefully managed deficit irrigation strategies that are supported by advanced irrigation system and flexible, state‐of‐the‐art water delivery systems. Nonagricultural water users will need to exercise patience as tools reflecting the paradigmatic shift are actualized. Both groups will need to cooperate and compromise as they practice more conservative approaches to freshwater consumption.

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“…Fruit growth measurement and analysis is therefore an important tool in assessing the impact ofRDI Mitchell et al 1989;Durand 1990;Pola et al 1991;Behboudian et al 1994;Mills et al 1996). In addition to using fruit growth data to assess the impact of RDI, researchers have also monitored fruit growth as a tool to schedule irrigation in fruit trees (Ebel et al 1995).…”

Section: Applications Of Fruit Growth Datamentioning

confidence: 99%

Fruit Growth Measurement and Analysis

Opara¹

1999

Horticultural Reviews

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Deficit Irrigation to Control Vegetative Growth in Apple and Monitoring Fruit Growth to Schedule Irrigation

Cited by 75 publications

References 11 publications

Morpho-physiological and Yield Responses of Sweet Potato (Ipomoea batatas (L.) Lam.) Genotypes to Frequency of Irrigation under Greenhouse Condition

Morpho-physiological and Yield Responses of Sweet Potato (Ipomoea batatas (L.) Lam.) Genotypes to Frequency of Irrigation under Greenhouse Condition

Methods and technologies to improve efficiency of water use

Fruit Growth Measurement and Analysis

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