Increase in pea productivity associated with irrigation management

Santos, Osvaldir Feliciano dos; Cunha, Fernando França da; Taira, Tiago Ledesma; Souza, Epitácio José de; Leal, Aguinaldo José Freitas

doi:10.1590/s0102-053620180205

Cited by 9 publications

(5 citation statements)

References 13 publications

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“…For the variables number of pods per plant and mass of pods per plant, no data were found in the literature on the estimation of plot size to evaluate these variables, leading to a wide variation in plot sizes used in the work with the crop. The plot sizes used by Cardoso et al (2012); Santos, Cunha, Taira, Souza, and Leal (2018); Singh et al (2019);and Zhang et al (2016) ranged from 10 to 420 plants per plot, which were higher than those obtained in the present study, thus indicating greater reliability in the published information. However, Carvalho, Rezende, Aquino, Freitas, and Oliveira (2012); Garcia, Ferreira, Figueiredo, and Santos (2010); Mahieu et al (2009); and Oliveira, Carvalho, Rezende, and Freitas (2011) used a plot size ranging from one to six plants; these values are below what was estimated in the present study and may have led to less experimental precision in these works.…”

Section: Plot Sizecontrasting

confidence: 64%

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Experimental plan for tests with pea

et al. 2021

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Correct experimental planning is important to obtain more reliable data with high experimental precision. In this way, the results obtained and the technical recommendations generated are more reliable and representative. Thus, the objective of this work is to estimate the plot and sample sizes and the number of repetitions for the variables (a) number of pods per plant and (b) mass of pods per plant for pea (Pisum sativum L.) cultivation. Uniformity tests were carried in the years 2016, 2017, and 2018 in the experimental area of the Crop Science Department at Federal University of Santa Maria. The cultivar used was Pea Grain 40, which has an indeterminate growth habit, with a cycle of 75-90 d and a cylindrical pod. The plot size for evaluating the number of pods per plant and the mass of pods per plant for pea cultivation is eight and nine plants, respectively. The sample size for evaluating the number of pods per plant and the mass of pods per plant is eight plants in the direction of the line with a half-width of the 20% confidence interval of the mean. For the variables number of pods per plant and pod mass per pea plant, 10 and 12 repetitions are required, respectively, to evaluate up to 20 treatments in a randomized block design and in the incomplete blocks design with up to 100 treatments for significant differences of 35% between treatment averages. INTRODUCTIONThe pea (Pisum sativum L.) is an annual herbaceous legume, with cultivars classified as being of determined and indeterminate growth. Cultivars that show indeterminate growth are used for edible pods production, whereas cultivars with determined growth are used for grain production (Filgueira, 2008). Worldwide, in 2018, the production of dry pea occupied 7.88 million ha of cultivated area, with a production of 13.53 million tons; the largest producers are Europe (38.8%), North and South America (33.6%), Asia (20.5%

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Section: Plot Sizecontrasting

confidence: 64%

“…The plot sizes used by Cardoso et al. (2012); Santos, Cunha, Taira, Souza, and Leal (2018); Singh et al. (2019); and Zhang et al.…”

Section: Discussionmentioning

confidence: 99%

Experimental plan for tests with pea

et al. 2021

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“…Corn ET was estimated using the modified FAO method (MFAO) (Bernardo et al, 2019;Mantovani et al, 2006). The MFAO method has been widely used in scientific studies in Brazil (Santos et al, 2018;Silva et al, 2018c;Venancio et al, 2019;Vicente et al, 2017). In addition, it has been widely applied in several Brazilians farms and in other countries by the company IRRIGER (http://www.irriger.com.br/ en-US/) (IRRIGER, 2019).…”

Section: Modified Fao Methodsmentioning

confidence: 99%

Evapotranspiration mapping of commercial corn fields in Brazil using SAFER algorithm

Venâncio

Mantovani

Amaral

et al. 2021

Sci. agric. (Piracicaba, Braz.)

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SAFER (Simple Algorithm for Evapotranspiration Retrieving) is a relatively new algorithm applied successfully to estimate actual crop evapotranspiration (ET) at different spatial scales of different crops in Brazil. However, its use for monitoring irrigated crops is scarce and needs further investigation. This study assessed the performance of SAFER to estimate ET of irrigated corn in a Brazilian semiarid region. The study was conducted in São Desidério, Bahia State, Brazil, in corn-cropped areas in no-tillage systems and irrigated by central pivots. SAFER algorithm with original regression coefficients (a = 1.8 and b =-0.008) was initially tested during the growing seasons of 2014, 2015, and 2016. SAFER performed very poorly for estimating corn ET, with RMSD values greater than 1.18 mm d-1 for 12 fields analyzed and NSE values < 0 in most fields. To improve estimates, SAFER regression coefficients were calibrated (using 2014 and 2015 data) and validated with 2016 data, with the resulting coefficients a and b equal to 0.32 and-0.0013, respectively. SAFER performed well for ET estimation after calibration, with r 2 and NSE values equal to 0.91 and RMSD = 0.469 mm d-1. SAFER also showed good performance (r 2 = 0.86) after validation, with the lowest RMSD (0.58 mm d-1) values for the set of 14 center pivots in this growing season. The results support the use of calibrated SAFER algorithm as a tool for estimating water consumption in irrigated corn fields in semiarid conditions.

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“…Improper irrigation scheduling with deficit quantity of water has led to water stress in pea production, causing a decrease in the evapotranspiration, growth parameters and pea yield [1]. Harmful effects of improper water management, such asover application of water, deficit application of water, effect of water on soil salinity, water stress, and lack of research to determine the optimum quantity of water in pea production, have been reported by many researchers [1][2][3]. An irrigation moisture regimen for green pea crop is crucial to optimize yield and avoid over-watering.…”

Section: Introductionmentioning

confidence: 99%

“…Different varieties of green pea with varying irrigation levels, viz., 50%, 75%, 100%, and 125% ETc were tested under the drip irrigation and found a decrease in the productivity of pea at an excess and deficit irrigation treatments [3]. Green pod yield decreased with an increase in drought conditions, occurringat the vegetative and flowering stages [6].…”

Section: Introductionmentioning

confidence: 99%

Real Time Soil Moisture (RTSM) Based Irrigation Scheduling to Improve Yield and Water-Use Efficiency of Green Pea (Pisum sativum L.) Grown in North India

Singh

Franco

et al. 2022

Agronomy

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A field experiment on green pea (Pisum Sativum L.) was conducted under drip irrigation to determine the irrigation schedule based on real-time soil moisture measurements with irrigation treatments (main plots) and fertilizer treatments (sub-plots) in a split-plot design with three replications. Main plots consisted of fourirrigation levels at different matric potential ranges (I1: −20 kPa; I2: −30 kPa; I3: −35 kPa; and I4: −40 kPa), while the sub-plots consisted of three fertigation levels (F1: 120%, F2: 100% and F3: 80%) of recommended dose of fertilizers (40:60:50 kg/ha of NPK). The tensiometer with digital pressure transducer transferred the soil matric potential data to the irrigation controller, which activated the solenoid valves for irrigation. Observations were collected on plant growth parameters, pod yield, and quality parameters. Descriptive statistics of different plant growth parameters were made. The higher SMP threshold (−20 kPa) and lower SMP threshold (−40 kPa) greatly reduced the yield and water-use efficiency. Considering the results, real-time soil moisture-based irrigation at the soil matric potential threshold level of −30 kPa with 120% of recommended dose of fertilizers through fertigation was recommended for attaining maximum green pea pod yield and water-use efficiency under semi-arid Inceptisols.

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Increase in pea productivity associated with irrigation management

Cited by 9 publications

References 13 publications

Experimental plan for tests with pea

Experimental plan for tests with pea

Evapotranspiration mapping of commercial corn fields in Brazil using SAFER algorithm

Real Time Soil Moisture (RTSM) Based Irrigation Scheduling to Improve Yield and Water-Use Efficiency of Green Pea (Pisum sativum L.) Grown in North India

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