Intercambio de gas y productividad de maracuyá amarillo irrigado bajo salinidad y fertilizado con potasio y biofertilizante

Nunes, Járisson Cavalcante; Cavalcante, Lourival Ferreira; Pereira, Walter Esfrain; Souza, José Thyago Aires; Almeida, Dácio Jerônimo de; Oresca, Denizard; Fernandes, Pedro Dantas

doi:10.7764/rcia.v44i2.1742

Cited by 8 publications

(5 citation statements)

References 15 publications

(34 reference statements)

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“…**: significant at 1% probability As noted by Dias, Cavalcante, Nunes, Freire, and Nascimento (2012), an increase in the electrical conductivity of irrigation water of 0.5 to 1.5 dS m -1 reduced passion fruit yield by 19%, while at a salinity of 3.5 dS m -1 , yields were reduced by 40%. The decrease observed in this study (45%) with the use of water of 4.0 dS m -1 reflects the sensitivity of passion fruit to saline water (Ayers & Westcot, 1999), with implications in physiology (Freire et al, 2014;Nunes et al, 2017). Lateral pit coating, even with the potential to maintain soil moisture and dilute the effects of salts (Cavalcante et al, 2005), was not effective in mitigating stress because, most likely, the moist root environment favored the absorption of the soil solution and, consequently, of salts.…”

Section: Resultsmentioning

confidence: 64%

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Saline Water, Pit Coating and Calcium Fertilization on Chlorophyll, Fluorescence, Gas Exchange and Production in Passion Fruit

Bezerra¹,

Cavalcante²,

Bezerra³

et al. 2019

JAS

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In plants sensitive to salinity, such as passion fruit, irrigation with saline water can cause physiological disturbances and reduce fruit production, necessitating the use of cultural practices that mitigate saline stress. The objective of this study was to evaluate the effects of water salinity, pit coating with high-strength polyethylene film, and calcium fertilization on the physiological and productive aspects of passion fruit ‘BRS Gigante Amarelo’. The treatments were arranged in split plot in the scheme 2WS × (2LP × 5DC), corresponding to water salinity (0.3 and 4.0 dS m-1) as the main plot, side coating of pits (without and with) doses of calcium (0; 30; 60; 90 and 120 kg ha-1). During the flowering phase, we evaluated leaf chlorophyll indices, fluorescence kinetics, and gas exchange. The increase in calcium doses up to 60 kg ha-1 increased leaf chlorophyll and quantum efficiency. The stomata did not restrict gas exchange, but salinity resulted in reduced net photosynthesis and plant production. The lateral coating of the pits intensified the reduction in salinity-promoted production, while calcium mitigated the effects of the salts. Entisol cultivated with passion fruit should not be irrigated with saline water of 4.0 dS m-1; lateral pit coating is not advised. In an Entisol with an initial calcium level of 1.92 cmolc dm-3, the recommended application dose is 60 kg ha-1 for passion fruit cultivation.

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Section: Resultsmentioning

confidence: 64%

“…Reduced photosynthesis in passion fruit, caused by water salinity, has also been observed by Nunes et al (2017), in full bloom, and by Freire et al (2014), at the end of the productive phase. However, the moist root environment, caused by the coating pit (Cavalcante et al, 2005), intensified the decline in the assimilation of…”

Section: Resultsmentioning

confidence: 84%

Saline Water, Pit Coating and Calcium Fertilization on Chlorophyll, Fluorescence, Gas Exchange and Production in Passion Fruit

Bezerra¹,

Cavalcante²,

Bezerra³

et al. 2019

JAS

Self Cite

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“…The semi-arid region of the Brazilian Northeast is characterized by high evapotranspiration rates, irregular rainfall, poor soil drainage and the water sources usually have electrical conductivity above 1.5 dS m -1 , which can limit agricultural production, causing morphological, physiological and biochemical alterations in plants, compromising fruit development, production and quality (NEVES et al, 2009;FREIRE et al, 2014;NUNES et al, 2017). The effects of salts at high levels in the soil manifest through alterations in physical and chemical attributes, which reduce the osmotic potential of the soil solution, and through the direct action of specific ions on the mineral nutrition of the plants, culminating in yield loss (CAVALCANTE et al, 2009;.…”

Section: Introductionmentioning

confidence: 99%

Water salinity and nitrogen fertilization in the production and quality of guava fruits

Bezerra¹,

Gheyi²,

Nobre³

et al. 2019

Biosci. J.

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Using nitrogen (N) to increase plant tolerance to salinity has been tested in many species. However, in addition to controversial results, most studies are conducted with annual species and/or in the initial growth stage and there are almost no studies with perennial fruit crops in the production stage. Thus, this study aimed to evaluate the production components and post-harvest quality of 'Paluma' guava irrigated with water of increasing salinity in soil fertilized with N. The experiment was carried out for two years in drainage lysimeters in an experimental area of the Federal University of Campina Grande (UFCG), Pombal, PB, Brazil. The experimental design was in randomized blocks, in 5 x 4 factorial scheme, with of five levels of water salinity-ECw (NaCl) (0.3, 1.1, 1.9, 2.7 and 3.5 dS m-1) and four N doses (ureia) (70, 100, 130 and 160% of the recommended dose-541.1 mg of N dm-3 of soil per year), with three replicates. Number of fruits, mean fruit weight, production per plant, polar and equatorial diameters of fruit and contents of soluble solids and ascorbic acid (vitamin C) decreased linearly with the increase in irrigation water salinity from 0.3 dS m-1. The interaction between water salinity and N doses and the isolated action of N did not interfere statistically with the studied variables.

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“…In northeastern Brazil, the rise in soil salinity is related to high evaporation rates, rainfall irregularity, and inadequate management of fertilizers and irrigation and drainage, which contribute to a significant increase in salt-affected areas (Nunes et al, 2017;Lima et al, 2020a;Moura et al, 2020). However, in this region, the practice of irrigation is essential to increase crop yield.…”

Section: Introductionmentioning

confidence: 99%

Leaching of salts and production of sour passion fruit irrigated with low- and high-salinity water

Nunes

Neto

Cavalcante

et al. 2023

Rev. bras. eng. agríc. ambient.

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The objective of this study was to evaluate the effect of irrigation with low- and high-salinity water on the increment of salts in the soil, the production components of sour passion fruit and the leaching of salts by rainfall and by leaching fraction of 10%. The treatments were arranged in randomized blocks, in a split-plot scheme, corresponding to three irrigation management practices [evaluation of soil chemical attributes before irrigation; and after irrigation with water of low electrical conductivity (0.35 dS m-1), and high electrical conductivity (4.00 dS m-1) in the main plot], and in the subplot two soil depths of evaluation (0-20 and 20-40 cm) and three soil sampling times (at 115 days after transplanting of seedlings (DAT) - beginning of flowering; at 199 DAT - end of the dry season; and at 379 DAT - end of the rainy season). Irrigation increased the electrical conductivity of the soil saturation extract, with higher values in the surface layer and at the end of the dry season. Rainfall during the rainy season reduced the saline character of soil from moderately saline and strongly saline, in treatments irrigated with water of low and high electrical conductivity, to non-saline and slightly saline, respectively. Irrigation with high-electrical conductivity water negatively affected the production components and yield of sour passion fruit.

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Intercambio de gas y productividad de maracuyá amarillo irrigado bajo salinidad y fertilizado con potasio y biofertilizante

Cited by 8 publications

References 15 publications

Saline Water, Pit Coating and Calcium Fertilization on Chlorophyll, Fluorescence, Gas Exchange and Production in Passion Fruit

Saline Water, Pit Coating and Calcium Fertilization on Chlorophyll, Fluorescence, Gas Exchange and Production in Passion Fruit

Water salinity and nitrogen fertilization in the production and quality of guava fruits

Leaching of salts and production of sour passion fruit irrigated with low- and high-salinity water

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