Phosphite as phosphorus source to grain yield of common bean plants grown in soils under low or adequate phosphate availability

Ávila, Fabrício William; Faquin, Valdemar; Silva, Douglas Ramos Guelfi; Bastos, Carla Elisa Alves; Oliveira, Nilma Portela; Soares, Danilo Araújo

doi:10.1590/s1413-70542012000600006

Cited by 5 publications

(4 citation statements)

References 20 publications

(19 reference statements)

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“…This variation results from a partial conversion of P +III to P +V in the presence of ambient air. 10 However, P +III recovery remained stable without considerable bias even after the adsorbed P +III was stored for three days as either a binding gel or eluent, as indicated in Figure 2-C. After 30 days of refrigeration, P +III recoveries of the retrieved binding gels and eluent decreased over time with a 54.8% and 78.7% retention, respectively.…”

Section: P +Iii Recovery Under Different Storage Conditions Effectivmentioning

confidence: 92%

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In situ sampling and speciation method for measuring dissolved phosphite at ultratrace concentrations in the natural environment

et al. 2018

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Phosphite (P) is of emerging chemical interest due to its importance within the global phosphorus cycle. Yet, to date, precise/accurate measurements of P are still lacking due to the inherent analytical challenges linked to its instability/ease of oxidation and ultra-trace concentration. Here, we present the first in-situ sampling and speciation analysis method, for dissolved P, using the diffusive-gradients-in-thin-films (DGT) technique, combined with capillary-column-configured-dual-ion-chromatography (CC-DIC). Method optimization of the DGT elution regime, to simultaneously maximize desorption efficiency and CC-DIC sensitivity, along with the characterization of diffusion coefficients for P, were undertaken before full method validation. Laboratory-performance testing confirmed DGT-P acquisition to be independent of pH (3.0-10.0) and ionic strength (0-500 mM). The capacity for P was 45.8 μg cm, while neither P (up to 10 mg L) nor As (up to 1 mg L) impacted the DGT-P measurement. This novel method's functionality stems from the herein confirmed speciation preservation and double pre-concentration of P, resulting in quantification limits as low as 7.44 ng L for a 3-day deployment. Applications of this method in various terrestrial/aquatic environments were demonstrated and simultaneous profiles of P and P across a sediment-water interface were captured at mm resolution in two contrasting redox-mesocosm systems.

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Section: P +Iii Recovery Under Different Storage Conditions Effectivmentioning

confidence: 92%

“…Several studies have also reported that P +III can be directly or indirectly utilized by plants, 9,10 microbes, 5,11 and algae. 12 However, its toxicity that P +III is most recognized for, and this is the primary concern for environmental monitoring programmes.…”

Section: Introductionmentioning

confidence: 99%

In situ sampling and speciation method for measuring dissolved phosphite at ultratrace concentrations in the natural environment

et al. 2018

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“…Ávila [80] grew common bean (Phaseolus vulgaris) in low and adequate soil Pi fertilized with increasing Phi (0 → 100 mg P dm −3 soil). In low Pi soil, Phi reduced plant growth and grain yield only when Phi was ≥25 mg P dm −3 soil; Phi toxicity symptoms were also observed.…”

Section: Phi Use As a Plant Nutrient Sourcementioning

confidence: 99%

Review of Phosphite as a Plant Nutrient and Fungicide

Havlin

Schlegel

2021

Soil Systems

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Phosphite (Phi)-containing products are marketed for their antifungal and nutritional value. Substantial evidence of the anti-fungal properties of Phi on a wide variety of plants has been documented. Although Phi is readily absorbed by plant leaves and/or roots, the plant response to Phi used as a phosphorus (P) source is variable. Negative effects of Phi on plant growth are commonly observed under P deficiency compared to near adequate plant P levels. Positive responses to Phi may be attributed to some level of fungal disease control. While only a few studies have provided evidence of Phi oxidation through cellular enzymes genetically controlled in plant cells, increasing evidence exists for the potential to manipulate plant genes to enhance oxidation of Phi to phosphate (Pi) in plants. Advances in genetic engineering to sustain growth and yield with Phi + Pi potentially provides a dual fertilization and weed control system. Further advances in genetic manipulation of plants to utilize Phi are warranted. Since Phi oxidation occurs slowly in soils, additional information is needed to characterize Phi oxidation kinetics under variable soil and environmental conditions.

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“…The common bean is a high demand plant for nutrients, and thus low natural soil fertility is one of the major factors that can limit productivity of this crop in tropical regions (Ávila et al, 2012;Fageria & Nascente, 2014;Argaw et al, 2015;Silva et al, 2016). Therefore, to avoid soil impoverishment and reduced productivity over time, it is necessary to replace at minimum the quantity of nutrients exported by the grains.…”

Section: Introductionmentioning

confidence: 99%

Phosphorus and potassium fertilization increase common bean grain yield in Mozambique

Carvalho

Nascente

Ferreira

et al. 2018

Rev. bras. eng. agríc. ambient.

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There is little information about common bean fertilization in African Savannas. The objectives of this study were as follows: i) to evaluate the common bean yield potential in the environmental conditions of Lichinga, Niassa, Mozambique, and ii) to determine the common bean response to phosphorus and potassium fertilization applied together in order to verify whether the interpretation of soil analysis for the Brazilian Cerrado could be adopted for Savanna soils in Mozambique. The experimental design was a randomized block design in a 5 x 4 x 2 factorial arrangement. Treatments consisted of a combination of phosphorus doses (0, 35, 70, 140 and 280 kg ha-1 of P2O5), potassium doses (0, 50 100 and 200 kg ha-1 of K2O), and different growing seasons (2012/2013 and 2013/2014). The field rainfed experiments were conducted in Lichinga city, province of Niassa. Common bean crops presented high productivity potential in rainfed systems in the environmental conditions of Lichinga, Niassa, Mozambique, reaching grain yields of up to 3,600 kg ha-1 depending on the rates of fertilization with phosphorus and potassium. Common beans responded to phosphorus and potassium fertilization despite high contents of these nutrients in the soil, according to the interpretation of soil analysis for the Brazilian Cerrado. Maximum grain yield in the average of two growing seasons was estimated to occur for 239 kg ha-1 of P2O5 and 141 kg ha-1 of K2O, indicating that further calibration studies for P and K are required for this specific region of Mozambique.

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Phosphite as phosphorus source to grain yield of common bean plants grown in soils under low or adequate phosphate availability

Cited by 5 publications

References 20 publications

In situ sampling and speciation method for measuring dissolved phosphite at ultratrace concentrations in the natural environment

In situ sampling and speciation method for measuring dissolved phosphite at ultratrace concentrations in the natural environment

Review of Phosphite as a Plant Nutrient and Fungicide

Phosphorus and potassium fertilization increase common bean grain yield in Mozambique

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