Foliar fertilization in Bermuda grass Discovery<sup>TM</sup>

Silvério, Jefferson Oliveira; Santos, Patrick Luan Ferreira dos; Nascimento, Matheus Vinícios Leal do; Souza, Camila Aparecida Nunes de; Costa, João Victor; Villas Bôas, Roberto Lyra

doi:10.1590/2447-536X.v26i3.2219

Abstract

Bermuda grass Discovery^TM is a new variety of ornamental and sports turfgrass with a unique color (bluish green), which has great potential to grow in Brazil. However, information regarding its development is still incipient, mainly related to the management of foliar fertilization. Thus, the aimed was to evaluate the development of Bermuda grass Discovery^TM based on doses of foliar fertilizer. The experiment was carried out in the experimental area, in 2019 autumn; and the experimental design was completely randomized, with 4 treatments and 3 repetitions, totaling 12 experimental plots of 1.5 m² each. The treatments were: 0 mL L^-1 (Control), 50 mL L^-1, 75 mL L^-1 and 100 mL L^-1 of the foliar fertilizer: NPK (6-2-3 + 20% amino acids). The applications were carried out with costal spray, in the late afternoon (17h), to avoid losses by evapotranspiration, and the evaluations were daily over 15 days. The following were evaluated: chemical analysis of the soil, green color index, height of the lawn, dry mass of the clippings and analysis by digital image. It was observed that with the doses increasing, there was better development and coloring of the lawn, showing that foliar fertilization is an effective and quick response method for the turfgrass, with the need for regular applications in an interval of 7 days to maintain the quality desired aesthetics. However, this variety presents low vertical growth, consequently less need for maintenance of cut compared to the other Bermuda grass. The dose of 75 mL L^-1 is recommended for the management of the species.

Keywords:
Cynodon dactylon; nutritional management; turfgrass

Resumo

A grama Bermuda Discovery^TM é uma nova variedade de gramado ornamental e esportivo de coloração única (verde azulada), e que tem grande potencial para crescer no Brasil. Entretanto informações referentes ao seu desenvolvimento ainda são incipientes, principalmente relacionados ao manejo da adubação foliar. Assim, objetivou-se avaliar o desenvolvimento de grama Bermuda Discovery^TM em função de doses de fertilizante foliar. O experimento foi realizado na área experimental, no outono de 2019; e o delineamento experimental foi inteiramente casualizado, com 4 tratamentos e 3 repetições, totalizando 12 parcelas experimentais de 1,5 m² cada. Os tratamentos foram: 0 mL L^-1 (Testemunha), 50 mL L^-1, 75 mL L^-1 e 100 mL L^-1 do fertilizante foliar: NPK (6-2-3 + 20% de aminoácidos). As aplicações foram realizadas com pulverizados costal, ao final da tarde (17h), para evitar perdas por evapotranspiração, e as avaliações foram diárias ao longo de 15 dias. Foram avaliados: análise química do solo, índice de coloração verde, altura do gramado, massa seca das aparas e analise por imagem digital. Observou-se que com o aumento das doses houve melhor desenvolvimento e coloração do gramado, mostrando que a adubação foliar é um método eficaz e de rápida resposta para a grama, havendo a necessidade de aplicações regulares em um intervalo de 7 dias para manter a qualidade estética desejada, entretanto a variedade apresenta baixo crescimento vertical, consequentemente menor necessidade de manutenção de corte comparada as demais gramas Bermudas. Recomenda-se para manejo da espécie a dose de 75 ml L^-1.

Palavras-chave:
Cynodon dactylon; manejo nutricional; gramado

Introduction

During the last few years, turfgrass have been cultivated for various purposes, be they landscape, recreational, sporting, ornamental and environmental (Santos et al., 2016SANTOS, P.L.F.; BARCELOS, J.P.Q.; CASTILHO, R.M.M. Diferentes substratos de um gramado ornamental para uso em telhados verdes. Periódico Técnico e Científico Cidades Verdes, v.4, n.10, p.81-94, 2016. DOI: http://dx.doi.org/10.17271/2317860441020161393
http://dx.doi.org/10.17271/2317860441020... ). The visual aspect (aesthetic) as the intense green color and density (closed lawn, without flaws), is of vital importance for the implantation and maintenance of species for ornamental and sporting purposes (Lima et al., 2012LIMA, C.P.; BACKES, C.; FERNANDES, D.M.; SANTOS, A.J.M.; GODOY, L.J.G.; VILLAS BÔAS, R.L. Uso de índices de refletância das folhas para o nível de nitrogênio em grama-bermuda. Ciência Rural, v.42, n.9, p.1568-1574, 2012. DOI: http://dx.doi.org/10.1590/S0103-84782012005000062
http://dx.doi.org/10.1590/S0103-84782012... ).

A great highlight on the national scene is the Bermuda grass (Cynodon spp.) (Santos et al., 2019SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.). They are species of hot season, originating in the African continent and naturalized in the Bermuda Islands, and have significant use in Brazil, due to their beauty, resistance to trampling, intense green and soft and thin leaves (Godoy et al., 2012GODOY, L.J.G.; VILLAS BÔAS, R.L.; BACKES, C.; SANTOS, A.J.M. Nutrição, Adubação e calagem para produção de gramas. Botucatu: FEPAF, 2012. 146p.). Furthermore, the varieties that have been used show rapid growth and development, which is essential for use in high performance sports fields such as football (Mateus et al., 2017MATEUS, C.M.D.; TAVARES, A.R.T.; OLIVEIRA, M.R.; JACON, C.P.R.P.; SARTORI, M.M.P.; FERNANDES, D.M.; VILLAS-BÔAS, R.L. Influence of substrate base on sports field covered with bermuda grass. Ornamental Horticulture, v.23, n.3, p.319-328, 2017. DOI: https://doi.org/10.14295/oh.v23i3.1104
https://doi.org/10.14295/oh.v23i3.1104... ). However, its use ends up being unfeasible for landscaping, since due to this characteristic, it increases the cost of maintaining turfgrass mowing (Santos and Castilho, 2018bSANTOS, P.L.F.; CASTILHO, R.M.M. Substrates in the development of a sports turfgrass “Tifton 419”. Ornamental Horticulture, v.24, n.4, p.138-144, 2018b. DOI: https://doi.org/10.14295/oh.v24i2.1155
https://doi.org/10.14295/oh.v24i2.1155... ).

Thus, as an alternative, it would be the use of a variety that has slow growth, to be used for ornamental purposes and in low traffic sports fields, such as golf fairway areas. And a species that corresponds to the desired characteristics is a new variety of Bermuda grass, known as Discovery^TM, or ‘Barazur’ (Khanal et al., 2017KHANAL, S.; SCHWARTZ, B.M.; KIM, C.; ADHIKARI, J.; RAINVILLE, L.K.; AUCKLAND, S.A.; PETERSON, A.H. Cross-taxon application of sugarcane EST-SSR to genetic diversity analysis of bermudagrass (Cynodon spp.). Genetic Resources and Crop Evolution, n.64, p.2059-2070, 2017. DOI: https://doi.org/10.1007/s10722-017-0496-2
https://doi.org/10.1007/s10722-017-0496-... ). This new turfgrass has a unique color with shades of dark blue-green (Bruijn, 2012BRUIJN, J. Bermuda grass plant named barazur. United States Plant Patent. n. PP22,963. Washington, DC: U.S. Deposit: 15 Sept. 2011. Concession: 14 Aug. 2012. Available at: <Available at: https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf >. Accessed on: June 20th 2019.
https://patentimages.storage.googleapis.... ). Thus, having a differential in a esthetic quality, with low maintenance, due to its reduced vertical growth, which makes it necessary to cut it only once a month, corresponding to 75% less pruning than the other varieties of the species (Qually Grama, 2019QUALLY GRAMA. Discovery Bermudagrass Less Mowing. 5p. Available at: <Available at: https://www.quallygrama.com.br/grama-discovery-lancamento.pdf >. Accessed on: June 20th 2019.
https://www.quallygrama.com.br/grama-dis... ).

However, as it is a new variety recently launched in Brazil, information about the species is limited, with no information on maintenance fertilization. And lawn areas need all the nutrients in essential quantities to express their exuberance and complete their development (Santos and Castilho, 2018aSANTOS, P.L.F.; CASTILHO, R.M.M. Resposta da grama esmeralda em função de diferentes fertilizantes e substratos. Cultura Agronômica, v.27, n.3, p.354-365, 2018a. DOI: https://doi.org/10.32929/2446-8355.2018v27n3p354-365
https://doi.org/10.32929/2446-8355.2018v... ). However, in São Paulo State, there is no official recommendation for fertilization for lawn maintenance, which ends up making the nutrition of turfgrass species with erroneous fertilizations much more difficult (Godoy et al., 2012GODOY, L.J.G.; VILLAS BÔAS, R.L.; BACKES, C.; SANTOS, A.J.M. Nutrição, Adubação e calagem para produção de gramas. Botucatu: FEPAF, 2012. 146p.). Thus, foliar fertilization could be an alternative to try to mitigate this information, since the response time is fast, and absorption is efficient. However, it is essential to search for the ideal dose so that the lawn can at the same time improve its aesthetic quality and have an excellent development.

Thus, knowing that Discovery^TM has great growth potential in Brazil and that information regarding its development is still incipient, the objective was to evaluate the response in the development of this variety according to different doses of leaf fertilizer.

Material and Methods

The work was carried out in an experimental area of 45.5 m² Discovery^TM Bermuda grass, 7 m long and 6.5 m wide, with sub-surface drip irrigation installed at a depth of 5 cm. The soil is characterized as Dystrophic Red Latosol (LVd), and the chemical characteristics are shown in Table 1.

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Table 1
Soil chemical analysis of the experimental area.

The climate in the region is called Cfa (humid subtropical climate with abundant precipitation and well distributed throughout the year), according to the Koppen climate classification. During the execution of the experiment, data on average temperature (20 ºC), average relative humidity (70%) and accumulated rainfall (8 mm) were obtained through the Meteorological Station located next to the experimental area. The drip irrigation was performed daily by replacing the previous day›s evapotranspirated blade, so that the water factor would not interfere with the results.

The 45.5 m² area was divided into 12 plots of 1.5 m² (1 x 1.5 m) with 0.5 m borders. The experimental design adopted was completely randomized, with 4 treatments (doses of foliar fertilizer) and 3 repetitions, being: 0 mL L^-1 (Control-without foliar fertilization); 50 mL L^-1; 75 mL L^-1; 100 mL L^-1.

The foliar fertilizer used was a formulated one (6-2-3) composed by the fertilizers: urea, potassium sulfate and monoammonium phosphate (MAP) with 20% more amino acids as a complexing agent.

The experiment was implemented in 2019 autumn, where the lawn was initially cut and maintained at a height of 15 mm. After cutting, the 1.5 m² plots were divided, with 0.5 m of border between them. The treatments were applied with a backpack sprayer, using a fan nozzle with an estimated flow rate of 350 L ha^-1, with the tank being washed after the application of each treatment. The sprayings were carried out in the late afternoon (17 h) to avoid loss by evaporation. The evaluations lasted 15 days being evaluated:

a) Green color index (GCI): Field Scout CM-1000 whose operating principle is based on light reflectance, making three readings in each plot, and their averages are calculated (0 to 999). Samples were obtained parallel to the surface of the turfgrass, at the same height (1.0 m). The results were obtained from the 1^st to the 14^th DAI (Days after the installation of the experiment).

b) Green color index (GCI): Light reflectance meter, which consists of the use of a device called Field Scout TCM 500 Turf Color Meter, which measures the reflection of light by the turfgrass in the red, green and blue spectrum. The device was placed in contact with the lawn and pressed so that there is no light penetration, which generates a “grass index” (0 to 9.9) and RGB values (Green, Blue and Red respectively). The “grass index” data were obtained daily from the 1_st to the 14^th DAI, with the RGB components in the 7^th and 14^th DAI, and converted into values of Hue (H), saturation (S) and brightness (B) of the lawn and later obtaining Dark Green Color Index (DGCI) data (Karcher and Richardson, 2003KARCHER, D.E.; RICHARDSON, M.D. Quantifying turfgrass color using digital image analysis. Crop Science, v.43, p.943-951, 2003. DOI: https://doi.org/10.2135/cropsci2003.9430
https://doi.org/10.2135/cropsci2003.9430... ).

c) Analysis of the visual aspect by digital image - Photographs of the area were taken with an 12Mp camera, fixed in a structure called “light box”, similar to that produced by Peterson et al. (2011PETERSON, K.; SHONKWILER, A.K.; BREMER, D. Custom light box for digital image turfgrass analysis. In: K-State Turfgrass Research. Kansas: K-State University Publications, 2011. p.89-91.). This structure is a completely sealed box with lamps connected to a battery, in order to standardize the brightness and the area photographed in all treatments. These images were transferred to a computer and placed on the side for better visualization of the treatments. This operation was performed on the 7th and 14th day after the installation of the experiment, obtaining one image per plot.

d) Turfgrass height - Data were collected daily from the 1st to the 14th day after the installation of the experiment, with the lawn height measuring instrument “Grass Height Prism Gauge” being measured three times per plot, in order to minimize the influence on the result of irregular areas.

e) Dry matter mass - The cut was made using the GreenMaster 1000 Toro^® machine leaving the lawn 15 mm high. Clippings were collected in order to evaluate the dry matter mass of the shoot of the lawn, after the samples were placed in an oven at 65 ºC for 72 h, and weighed on a precision scale of 0.01.

Thus, the results were submitted through analysis of variance (ANAVA) and Tukey›s test at the level of 5% probability for comparison of means, using the program “Statistix 10” for data analysis.

Results and Discussions

The results obtained for GCI with the Field Scout CM1000 (Table 2) shows the evolution over time of this variable. It was observed that on the 1^st day after the installation of the experiment, there was no statistically difference, possibly due to the leaf fertilizer that had not yet been fully absorbed by the leaves. As of the 2^nd day, 75 and 100 mL L^-1 showed the best results, and these are the highest doses used respectively. Over the days, linearity in the values was maintained, where mentioned treatments, obtained the best GCI in general. However, after the 9^th day, a decrease in the results of 50, 75 and 100 mL L^-1 was observed.

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Table 2
Green color index (GCI) obtained with the Field Scout CM1000 Chlorophyl Meter throughout the experiment.

When the N dose is high from a deficiency situation, there is an increase in the chlorophyll content, providing a linear response regarding the green color of the turfgrass (Gazola et al., 2016GAZOLA, R.P.D.; BUZETTI, S.; GAZOLA, R.N.; CASTILHO, R.M.M.; TEIXEIRA FILHO, M.C.M.; CELESTRINO, T.S.; DUPA, E. Nitrogen dose and type of herbicide used for growth regulation on the green coloration intensity of Emerald grass. Ciência Rural, v.46, n.6, p.984-990, 2016. DOI: http://dx.doi.org/10.1590/0103-8478cr20150276
http://dx.doi.org/10.1590/0103-8478cr201... ). Also, according to Santos and Castilho (2015SANTOS, P.L.F.; CASTILHO, R.M.M. Relação entre teor de clorofila e nitrogênio foliar em grama esmeralda cultivada em substratos. Tecnologia & Ciência Agropecuária , v.9, n.2, p.51-54, 2015.) the green color index, indirectly reflects the amount of chlorophyll in the leaves and the N foliar. Since the chlorophylls are magnesian porphyrins, with a central magnesium atom attached to 4 nitrogen atoms (Taiz et al., 2017TAIZ, L.; ZEIGER, E.; MÜLLER, I.M.; MURPHY, A. Fisiologia e desenvolvimento vegetal. 6ed. Porto Alegre: Artmed, 2017. 858p.), and as the fertilizer used had 6% N, the highest doses provided greater amounts of this nutrient, which possibly explains the results found.

Decrease in the green coloration index can be explained due to the reduction of the N concentration in the leaf, once the maximum fertilizer absorption is reached, there is a dilution of the nutrient resided in the leaf with the growth of its mass (Lima et al., 2012LIMA, C.P.; BACKES, C.; FERNANDES, D.M.; SANTOS, A.J.M.; GODOY, L.J.G.; VILLAS BÔAS, R.L. Uso de índices de refletância das folhas para o nível de nitrogênio em grama-bermuda. Ciência Rural, v.42, n.9, p.1568-1574, 2012. DOI: http://dx.doi.org/10.1590/S0103-84782012005000062
http://dx.doi.org/10.1590/S0103-84782012... ; Taiz et al., 2017TAIZ, L.; ZEIGER, E.; MÜLLER, I.M.; MURPHY, A. Fisiologia e desenvolvimento vegetal. 6ed. Porto Alegre: Artmed, 2017. 858p.; Santos et al., 2019SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.). This clarifies the indexes found after the 9^th day, in treatments 50, 75 and 100 mL L^-1, where the amount of N became insufficient to maintain the color that it had reached, due to the growth of the lawn. At 0 mL L^-1, the indexes remained statistically constant, possibly because the N concentration was naturally maintained.

Foliar fertilizers have a fast absorption and are efficient, the answers happen around 24 to 48 hours after application, as reported by Coelho (2018COLEHO, A.M. Adubação foliar em milho utilizando fertilizantes multinutrientes. Campo & Negócios, v.15, n.178, p.26-29, 2018.). Exactly in the same period that the beginning of the increase in GCI and the statistical difference between treatments can be observed (1^st to 2^nd DAI).

Regular applications, with lower doses in a 7 to 14 day schedule, may be advised for maintenance, due to the drop in values observed in the present study, mainly from the 10^th to the 12^th day. However, at the end of the 14^th day, there is still a response to the first fertilization, and there may be a greater residual effect.

Godoy et al. (2012GODOY, L.J.G.; VILLAS BÔAS, R.L.; BACKES, C.; SANTOS, A.J.M. Nutrição, Adubação e calagem para produção de gramas. Botucatu: FEPAF, 2012. 146p.) state that fertilization is vitally important to complete the amount of nutrients available in the soil, and thus supply the demand for turfgrass. And 75 and 100 mL L^-1 showed better performances (reaching 74% higher than control on the 7^th day), however, such treatments did not differ statistically. This suggests that the demand for Discovery^TM Bermuda grass has already been met with the dose of 75 mL L^-1, and there may be excess and, consequently, waste of fertilizer in 100 mL L^-1. Therefore, the recommendation for the application of 75 mL L^-1, provides greater savings, with the reduction of fertilizer applied, for the same result in the quality of the lawn.

The green color indices acquired with the Field Scout TCM 500 device (Table 3), corroborate the linearity of the data obtained in Table 2.

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Table 3
Green color index obtained with the Field Scout TCM 500 Turf Color Meter throughout the experiment.

There was no response from the application after the 1^st day, possibly due to the total non-absorption of the fertilizer, which happened after the 2^nd day, where there was an increase in the rates. The drop in results also occurred from the 9^th day after application, as a result of the growth of the lawn, but reaching the 14^th with differentiation of the witness. 75 and 100 mL L^-1 obtained the best results, still not differing statistically, reinforcing the dose of 75 mL L^-1 as the best option in the application.

Thus, regardless of the reflectance device used, the green color index is efficient for analyzing the development of the turfgrass, especially with regard to N foliar. Lima et al. (2012LIMA, C.P.; BACKES, C.; FERNANDES, D.M.; SANTOS, A.J.M.; GODOY, L.J.G.; VILLAS BÔAS, R.L. Uso de índices de refletância das folhas para o nível de nitrogênio em grama-bermuda. Ciência Rural, v.42, n.9, p.1568-1574, 2012. DOI: http://dx.doi.org/10.1590/S0103-84782012005000062
http://dx.doi.org/10.1590/S0103-84782012... ) also found a correlation between the different green color indices used in the present study for indirect determination of N in Bermuda grass. Santos et al. (2019SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.) found that photosynthetic pigments indirectly show the nutrition of Bermuda grass for the nutrients of N and Mg, and consequently provide the most intense green when in greater quantities. Oliveira et al. (2018OLIVEIRA, N.B.; OLIVEIRA, J.F.V.; SANTOS, P.L.F.; GAZOLA, R.P.D.; CASTILHO, R.M.M. Avaliação do estado nutricional de três gramados ornamentais em Ilha Solteira-SP: um estudo de caso. Revista LABVERDE, v.9, n.1, p.96-119, 2018. DOI: http://dx.doi.org/10.11606/issn.2179-2275.v9i1p96-119
http://dx.doi.org/10.11606/issn.2179-227... ) confirmed the same correlation between GCI and Nitrogen in Emerald grass (Zoysia japonica).

The GCI values obtained, therefore, must be related to the values of the components of green color, hue, saturation, brightness and dark green color index, thus also having linearity in the data, as shown by the results obtained for these parameters (Table 4).

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Table 4
Analysis of the component of green (G), Hue (H), Saturation (S), Brightness (B) and Dark Green Color Index (DGCI) at 7 and 14 days after installation of the experiment.

At 7 DAI, it can be seen that the green and hue component showed positive responses to application in treatments 50, 75 and 100 mL L^-1, but did not differ statistically between them. With an increase in relation to the control for the green component of 26.53%, 33.67% and 33.67% and for the hue of 19.44%, 27.77% and 29.16% for 50, 75 and 100 mL L^-1 respectively. Saturation and brightness were contradictory to other results, presenting 50 mL L^-1 with a better performance. This may have occurred due to the characteristics of the variety in question; Discovery^TM Bermuda grass has a darker color than the standard in its ideal, being considered dark blue-green (Bruijn, 2012BRUIJN, J. Bermuda grass plant named barazur. United States Plant Patent. n. PP22,963. Washington, DC: U.S. Deposit: 15 Sept. 2011. Concession: 14 Aug. 2012. Available at: <Available at: https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf >. Accessed on: June 20th 2019.
https://patentimages.storage.googleapis.... ). As a result of this, the dark green component once again highlights the 75 and 100 mL L^-1 with better performances.

At the end of the experiment (14^th DAI), 75 and 100 mL L^-1 returned to obtain the greatest results, differing from the other treatments, except in the dark green component, showing a lack of characterization in their visual aspect, possibly due to the decrease in chlorophyll concentrations.

The turfgrass GCI is important due to its aesthetic aspect, that is, it must have good density and intense green color (Lima et al., 2012LIMA, C.P.; BACKES, C.; FERNANDES, D.M.; SANTOS, A.J.M.; GODOY, L.J.G.; VILLAS BÔAS, R.L. Uso de índices de refletância das folhas para o nível de nitrogênio em grama-bermuda. Ciência Rural, v.42, n.9, p.1568-1574, 2012. DOI: http://dx.doi.org/10.1590/S0103-84782012005000062
http://dx.doi.org/10.1590/S0103-84782012... ). And chlorophylls are responsible for this green hue in plants and, the higher the concentration in leaf contents, the more intense the color of a turfgrass (Oliveira et al., 2018OLIVEIRA, N.B.; OLIVEIRA, J.F.V.; SANTOS, P.L.F.; GAZOLA, R.P.D.; CASTILHO, R.M.M. Avaliação do estado nutricional de três gramados ornamentais em Ilha Solteira-SP: um estudo de caso. Revista LABVERDE, v.9, n.1, p.96-119, 2018. DOI: http://dx.doi.org/10.11606/issn.2179-2275.v9i1p96-119
http://dx.doi.org/10.11606/issn.2179-227... ; Santos et al., 2019SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.). Thus, it is inferred that the results obtained show that at 7 DAI (Table 4), there was a higher concentration of chlorophylls in 75 and 100 mL L^-1.

These results are extremely important, since chlorophylls a are responsible for converting light radiation into chemical energy, in the form of ATP and NADPH, and the higher the concentration of these pigments, the greater the green tint, and the better the photosynthetic efficacy of the lawn (Taiz et al., 2017TAIZ, L.; ZEIGER, E.; MÜLLER, I.M.; MURPHY, A. Fisiologia e desenvolvimento vegetal. 6ed. Porto Alegre: Artmed, 2017. 858p.; Santos et al., 2019SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.).

The visual aspect of each treatment at 7 (Figure 1) and 14 (Figure 2) days after the application of the foliar fertilizer, visually shows the aesthetics of the turfgrass, where with the increase of the doses, there was greater green coloring, corroborating with the data of GCI and DCGI previously obtained. According to Bruijn (2012BRUIJN, J. Bermuda grass plant named barazur. United States Plant Patent. n. PP22,963. Washington, DC: U.S. Deposit: 15 Sept. 2011. Concession: 14 Aug. 2012. Available at: <Available at: https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf >. Accessed on: June 20th 2019.
https://patentimages.storage.googleapis.... ) the Discovery^TM coloring is different, darker than the standard (bluish green), being attractive to the ornamental sector, and on the 7^th day this coloring reached its peak, becoming evident to the naked eye.

Figure 1
Visual aspect of the turfgrass 7 days after the installation of the experiment.

Figure 2
Visual aspect of the turfgrass 14 days after the installation of the experiment.

The correlation between digital image, DCGI and N in Bermuda grass was verified in an experiment conducted by Catureglia et al. (2020CATUREGLI, L.; GAETANI, M.; VOLTERRANI, M.; MAGNI, S.; MINELLI, A.; BALDI, A.; BRANDANI, G.; MANCINI, M.; LENZI, A.; ORLANDINI, S.; LULLI, F.; BERTOLDI, C.; DUBBINI, M.; GROSSI, N. Normalized difference vegetation index versus dark green colour index to estimate nitrogen status on bermudagrass hybrid and tall fescue. International Journal of Remote Sensing, v.41, n.2, p.455-470, 2020. DOI: https://doi.org/10.1080/01431161.2019.1641762
https://doi.org/10.1080/01431161.2019.16... ), showing that photographs, in conjunction with other equipment can be an alternative for estimating turfgrass nutrition. Figure 1 shows the visual quality in the 75 and 100 mL L^-1, showing a better density and color, a consequence of the greater availability of the nutrient, followed by 0 and 50 mL L^-1, with low color intensity, making it possible to visualize a yellowish aspect straw on the lawn.

However, as the days went by, the turfgrass lost its color, as already mentioned, reaching the 14 days with less shades, this caused the visual aspect to also be perceived (Figure 2), with a drop in the bluish-green when compared to 7 DAI (Figure 1). Thus, aesthetically, the turfgrass has become less dense and has less green color, which is not desirable for ornamental lawns, thus inferring that the duration of foliar fertilization is a few days, and must be carried out periodically.

As the increase in doses provided higher levels of green color in the lawn, the height of the leaves also came to be influenced (Table 5), because when the doses of N are high, it causes greater growth of the turfgrass (Gazola et al., 2019GAZOLA, R.P.D.; BUZETTI, S.; GAZOLA, R.N.; CASTILHO, R.M.M.; TEIXEIRA FILHO, M.C.M.; CELESTRINO, T.S. Nitrogen fertilization and glyphosate doses as growth regulators in Esmeralda grass. Revista Brasileira de Engenharia Agrícola e Ambiental, v.23, n.12, p.930-936, 2019. DOI: https://doi.org/10.1590/1807-1929/agriambi.v23n12p930-936
https://doi.org/10.1590/1807-1929/agriam... ). The height of the lawn began to differ statistically between treatments on the 4^th day after fertilization, with 75 and 100 mL L^-1 growing faster than 50 and 0 mL L^-1, with up to 4.6% difference between 75 100 mL L^-1 and the control. However, the very next day, the 5^th after fertilization, 50 mL L^-1 differs from 0 mL L^-1, with a 2.6% increase in 50 mL L^-1. Thus it continues until the end of the experiment, ending with 75 and 100 mL L^-1 with the fastest growth than the others, due to the greater availability of applied nutrients. Even though 100 mL L^-1 received a greater source of N than 75 mL L^-1, its heights did not differ statistically, possibly due to the inability of the leaf to absorb more N than necessary. Still, it is essential to emphasize that the faster growth of the lawn results in a greater need for maintenance for the cut, and also causes a greater loss of nutrients by the clippings.

Thumbnail

Table 5
Height of the turfgrass throughout the experiment.

Discovery^TM Bermuda grass presents a differential in aesthetic quality, with low maintenance, due to its reduced vertical growth (Qually Grama, 2019QUALLY GRAMA. Discovery Bermudagrass Less Mowing. 5p. Available at: <Available at: https://www.quallygrama.com.br/grama-discovery-lancamento.pdf >. Accessed on: June 20th 2019.
https://www.quallygrama.com.br/grama-dis... ), and this fact is observed in the present work, as the maximum growth reaching after 14 days was 5.3 mm in 100 mL L^-1, which corresponds to a rate of 35.8% in relation to the 1^st day evaluated. The Witness that did not undergo fertilization grew only 2.7 mm (17.9%). Amaral et al. (2016AMARAL, J.A.; CASTILHO, R.M.M.; HAGA, K.I. Efeito de diferentes condições de luminosidade e substratos no desenvolvimento inicial de grama bermuda. Cultura Agronômica, v.25, n.3, p.291-302, 2016. DOI: https://doi.org/10.32929/2446-8355.2016v25n3p291-302
https://doi.org/10.32929/2446-8355.2016v... ) working with Bermuda grass ‘Tifway 419’ observed that after 30 days, the growth of the lawn was accelerated, where the witness who did not undergo any type of handling reached 75 mm. For the ‘Tifdwarf’ Bermuda grass, used in golf course greens, growth is even more accelerated, undergoes excessive pruning (Agnihotri et al., 2017AGNIHOTRI, R.; CHAWLA, S.L.; PATIL, S. Evaluation of warm season turfgrasses for various qualitative and quantitative traits under Gujarat agro-climatic conditions. Indian Journal of Agricultural Sciences, v.87, n.7, p.83-91, 2017.). Corroborating the fact that the studied species has slow vertical growth.

Thus, the results found in the present study show the potential of Discovery^TM Bermuda grass to be used for low maintenance turfgrass, due to its slow growth of the aerial part, even managed with NPK foliar fertilization. What is desirable for ornamental lawns, where due to this characteristic, the cost for cutting maintenance decreases (Santos and Castilho, 2018aSANTOS, P.L.F.; CASTILHO, R.M.M. Resposta da grama esmeralda em função de diferentes fertilizantes e substratos. Cultura Agronômica, v.27, n.3, p.354-365, 2018a. DOI: https://doi.org/10.32929/2446-8355.2018v27n3p354-365
https://doi.org/10.32929/2446-8355.2018v... ).

As previously described, N is the nutrient that most stimulates turfgrass growth, due to the increase in chlorophyll content, which ends up reflecting on the dry mass produced, and this fact corroborates with the data from the present study (Table 6). After 15 days of the application of leaf fertilizer, 75 and 100 mL L^-1 showed the highest dry mass of the clippings (4.6 and 4.7 g m^-2 respectively), and those doses presented the highest values of GCI (Tables 2 and 3), and the data are thus correlated. This fact was also observed by Santos and Castilho (2016SANTOS, P.L.F.; CASTILHO, R.M.M. Caracterização físico-química de diferentes substratos e sua influência no desenvolvimento da grama esmeralda. Tecnologia & Ciência Agropecuária, v.10, n.6, p.21-26, 2016.) in emerald grass, where the treatments with higher GCI showed greater dry mass of the leaves.

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Table 6
Clippings dry mass of the Discovery^TM bermuda grass.

The treatments 75 and 100 mL L^-1 did not differ statistically, and with that, it can be concluded that the foliar fertilization in the dose used in 75 mL L^-1 would be enough for a quick response in the development of the lawn. However, it is noteworthy that there was a large difference in mass produced between treatments, where 100 mL L^-1 was 2.2 times greater than the control. However, the observed values are lower than the dry mass produced by other Bermuda grass varieties, such as those of ‘Celebration’ (Lima et al., 2015LIMA, C.P.; BACKES, C.; SANTOS, A.J.M.; FERNANDES, D.M.; VILLAS BÔAS, R.L.; OLIVEIRA, M.R. Quantidade de nutrientes extraídos pela grama bermuda em função de doses de nitrogênio. Bioscience Journal, v.1, n.5, p.1432-1440, 2015. DOI: https://doi.org/10.14393/BJ-v31n5a2015-21967
https://doi.org/10.14393/BJ-v31n5a2015-2... ), ‘Tifdwarf’ (Agnihotri et al., 2017AGNIHOTRI, R.; CHAWLA, S.L.; PATIL, S. Evaluation of warm season turfgrasses for various qualitative and quantitative traits under Gujarat agro-climatic conditions. Indian Journal of Agricultural Sciences, v.87, n.7, p.83-91, 2017.) and ‘Tifway 419’ (Amaral et al., 2016AMARAL, J.A.; CASTILHO, R.M.M.; HAGA, K.I. Efeito de diferentes condições de luminosidade e substratos no desenvolvimento inicial de grama bermuda. Cultura Agronômica, v.25, n.3, p.291-302, 2016. DOI: https://doi.org/10.32929/2446-8355.2016v25n3p291-302
https://doi.org/10.32929/2446-8355.2016v... ; Mateus et al., 2017MATEUS, C.M.D.; TAVARES, A.R.T.; OLIVEIRA, M.R.; JACON, C.P.R.P.; SARTORI, M.M.P.; FERNANDES, D.M.; VILLAS-BÔAS, R.L. Influence of substrate base on sports field covered with bermuda grass. Ornamental Horticulture, v.23, n.3, p.319-328, 2017. DOI: https://doi.org/10.14295/oh.v23i3.1104
https://doi.org/10.14295/oh.v23i3.1104... ; Santos and Castilho, 2018bSANTOS, P.L.F.; CASTILHO, R.M.M. Substrates in the development of a sports turfgrass “Tifton 419”. Ornamental Horticulture, v.24, n.4, p.138-144, 2018b. DOI: https://doi.org/10.14295/oh.v24i2.1155
https://doi.org/10.14295/oh.v24i2.1155... ), thus showing that the volume of mass produced correlates with the height of the lawn, showing that the species has a low maintenance need.

This result should be highlighted, since the maintenance of turfgrass has a significant cost and the choice of cultivar has a direct influence on this characteristic. These data corroborate what Qually Grama (2019QUALLY GRAMA. Discovery Bermudagrass Less Mowing. 5p. Available at: <Available at: https://www.quallygrama.com.br/grama-discovery-lancamento.pdf >. Accessed on: June 20th 2019.
https://www.quallygrama.com.br/grama-dis... ) points out, which states that with this material it is possible to make only one cut per month, considerably reducing maintenance costs.

Conclusions

Foliar fertilization is an effective and quick response method for Discovery^TM Bermuda grass, with the need for regular applications over an interval of 7 days to maintain the desired aesthetic quality, using the dose of 75 mL L^-1 of NPK (6-2-3). The variety presents low vertical growth, consequently less need for maintenance of cut compared to the other Bermuda grass.

Acknowledgements

The authors are grateful to the World Sports^® Company for the collaboration to carry out the experiment.

References

AGNIHOTRI, R.; CHAWLA, S.L.; PATIL, S. Evaluation of warm season turfgrasses for various qualitative and quantitative traits under Gujarat agro-climatic conditions. Indian Journal of Agricultural Sciences, v.87, n.7, p.83-91, 2017.
AMARAL, J.A.; CASTILHO, R.M.M.; HAGA, K.I. Efeito de diferentes condições de luminosidade e substratos no desenvolvimento inicial de grama bermuda. Cultura Agronômica, v.25, n.3, p.291-302, 2016. DOI: https://doi.org/10.32929/2446-8355.2016v25n3p291-302
» https://doi.org/10.32929/2446-8355.2016v25n3p291-302
BRUIJN, J. Bermuda grass plant named barazur. United States Plant Patent. n. PP22,963. Washington, DC: U.S. Deposit: 15 Sept. 2011. Concession: 14 Aug. 2012. Available at: <Available at: https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf >. Accessed on: June 20^th 2019.
» https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf
CATUREGLI, L.; GAETANI, M.; VOLTERRANI, M.; MAGNI, S.; MINELLI, A.; BALDI, A.; BRANDANI, G.; MANCINI, M.; LENZI, A.; ORLANDINI, S.; LULLI, F.; BERTOLDI, C.; DUBBINI, M.; GROSSI, N. Normalized difference vegetation index versus dark green colour index to estimate nitrogen status on bermudagrass hybrid and tall fescue. International Journal of Remote Sensing, v.41, n.2, p.455-470, 2020. DOI: https://doi.org/10.1080/01431161.2019.1641762
» https://doi.org/10.1080/01431161.2019.1641762
COLEHO, A.M. Adubação foliar em milho utilizando fertilizantes multinutrientes. Campo & Negócios, v.15, n.178, p.26-29, 2018.
GAZOLA, R.P.D.; BUZETTI, S.; GAZOLA, R.N.; CASTILHO, R.M.M.; TEIXEIRA FILHO, M.C.M.; CELESTRINO, T.S. Nitrogen fertilization and glyphosate doses as growth regulators in Esmeralda grass. Revista Brasileira de Engenharia Agrícola e Ambiental, v.23, n.12, p.930-936, 2019. DOI: https://doi.org/10.1590/1807-1929/agriambi.v23n12p930-936
» https://doi.org/10.1590/1807-1929/agriambi.v23n12p930-936
GAZOLA, R.P.D.; BUZETTI, S.; GAZOLA, R.N.; CASTILHO, R.M.M.; TEIXEIRA FILHO, M.C.M.; CELESTRINO, T.S.; DUPA, E. Nitrogen dose and type of herbicide used for growth regulation on the green coloration intensity of Emerald grass. Ciência Rural, v.46, n.6, p.984-990, 2016. DOI: http://dx.doi.org/10.1590/0103-8478cr20150276
» http://dx.doi.org/10.1590/0103-8478cr20150276
GODOY, L.J.G.; VILLAS BÔAS, R.L.; BACKES, C.; SANTOS, A.J.M. Nutrição, Adubação e calagem para produção de gramas. Botucatu: FEPAF, 2012. 146p.
KARCHER, D.E.; RICHARDSON, M.D. Quantifying turfgrass color using digital image analysis. Crop Science, v.43, p.943-951, 2003. DOI: https://doi.org/10.2135/cropsci2003.9430
» https://doi.org/10.2135/cropsci2003.9430
KHANAL, S.; SCHWARTZ, B.M.; KIM, C.; ADHIKARI, J.; RAINVILLE, L.K.; AUCKLAND, S.A.; PETERSON, A.H. Cross-taxon application of sugarcane EST-SSR to genetic diversity analysis of bermudagrass (Cynodon spp.). Genetic Resources and Crop Evolution, n.64, p.2059-2070, 2017. DOI: https://doi.org/10.1007/s10722-017-0496-2
» https://doi.org/10.1007/s10722-017-0496-2
LIMA, C.P.; BACKES, C.; FERNANDES, D.M.; SANTOS, A.J.M.; GODOY, L.J.G.; VILLAS BÔAS, R.L. Uso de índices de refletância das folhas para o nível de nitrogênio em grama-bermuda. Ciência Rural, v.42, n.9, p.1568-1574, 2012. DOI: http://dx.doi.org/10.1590/S0103-84782012005000062
» http://dx.doi.org/10.1590/S0103-84782012005000062
LIMA, C.P.; BACKES, C.; SANTOS, A.J.M.; FERNANDES, D.M.; VILLAS BÔAS, R.L.; OLIVEIRA, M.R. Quantidade de nutrientes extraídos pela grama bermuda em função de doses de nitrogênio. Bioscience Journal, v.1, n.5, p.1432-1440, 2015. DOI: https://doi.org/10.14393/BJ-v31n5a2015-21967
» https://doi.org/10.14393/BJ-v31n5a2015-21967
MATEUS, C.M.D.; TAVARES, A.R.T.; OLIVEIRA, M.R.; JACON, C.P.R.P.; SARTORI, M.M.P.; FERNANDES, D.M.; VILLAS-BÔAS, R.L. Influence of substrate base on sports field covered with bermuda grass. Ornamental Horticulture, v.23, n.3, p.319-328, 2017. DOI: https://doi.org/10.14295/oh.v23i3.1104
» https://doi.org/10.14295/oh.v23i3.1104
OLIVEIRA, N.B.; OLIVEIRA, J.F.V.; SANTOS, P.L.F.; GAZOLA, R.P.D.; CASTILHO, R.M.M. Avaliação do estado nutricional de três gramados ornamentais em Ilha Solteira-SP: um estudo de caso. Revista LABVERDE, v.9, n.1, p.96-119, 2018. DOI: http://dx.doi.org/10.11606/issn.2179-2275.v9i1p96-119
» http://dx.doi.org/10.11606/issn.2179-2275.v9i1p96-119
PETERSON, K.; SHONKWILER, A.K.; BREMER, D. Custom light box for digital image turfgrass analysis. In: K-State Turfgrass Research. Kansas: K-State University Publications, 2011. p.89-91.
QUALLY GRAMA. Discovery Bermudagrass Less Mowing. 5p. Available at: <Available at: https://www.quallygrama.com.br/grama-discovery-lancamento.pdf >. Accessed on: June 20^th 2019.
» https://www.quallygrama.com.br/grama-discovery-lancamento.pdf
SANTOS, P.L.F.; BARCELOS, J.P.Q.; CASTILHO, R.M.M. Diferentes substratos de um gramado ornamental para uso em telhados verdes. Periódico Técnico e Científico Cidades Verdes, v.4, n.10, p.81-94, 2016. DOI: http://dx.doi.org/10.17271/2317860441020161393
» http://dx.doi.org/10.17271/2317860441020161393
SANTOS, P.L.F.; CASTILHO, R.M.M. Caracterização físico-química de diferentes substratos e sua influência no desenvolvimento da grama esmeralda. Tecnologia & Ciência Agropecuária, v.10, n.6, p.21-26, 2016.
SANTOS, P.L.F.; CASTILHO, R.M.M. Relação entre teor de clorofila e nitrogênio foliar em grama esmeralda cultivada em substratos. Tecnologia & Ciência Agropecuária , v.9, n.2, p.51-54, 2015.
SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.
SANTOS, P.L.F.; CASTILHO, R.M.M. Resposta da grama esmeralda em função de diferentes fertilizantes e substratos. Cultura Agronômica, v.27, n.3, p.354-365, 2018a. DOI: https://doi.org/10.32929/2446-8355.2018v27n3p354-365
» https://doi.org/10.32929/2446-8355.2018v27n3p354-365
SANTOS, P.L.F.; CASTILHO, R.M.M. Substrates in the development of a sports turfgrass “Tifton 419”. Ornamental Horticulture, v.24, n.4, p.138-144, 2018b. DOI: https://doi.org/10.14295/oh.v24i2.1155
» https://doi.org/10.14295/oh.v24i2.1155
TAIZ, L.; ZEIGER, E.; MÜLLER, I.M.; MURPHY, A. Fisiologia e desenvolvimento vegetal. 6ed. Porto Alegre: Artmed, 2017. 858p.

Area Editor: Ana Maria Mapeli

Publication Dates

Publication in this collection
18 Sept 2020
Date of issue
Jul-Sep 2020

History

Received
16 June 2020
Accepted
03 Aug 2020
Published
14 Aug 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] AGNIHOTRI, R.; CHAWLA, S.L.; PATIL, S. Evaluation of warm season turfgrasses for various qualitative and quantitative traits under Gujarat agro-climatic conditions. Indian Journal of Agricultural Sciences, v.87, n.7, p.83-91, 2017.

[2] AMARAL, J.A.; CASTILHO, R.M.M.; HAGA, K.I. Efeito de diferentes condições de luminosidade e substratos no desenvolvimento inicial de grama bermuda. Cultura Agronômica, v.25, n.3, p.291-302, 2016. DOI: https://doi.org/10.32929/2446-8355.2016v25n3p291-302
» https://doi.org/10.32929/2446-8355.2016v25n3p291-302

[3] BRUIJN, J. Bermuda grass plant named barazur. United States Plant Patent. n. PP22,963. Washington, DC: U.S. Deposit: 15 Sept. 2011. Concession: 14 Aug. 2012. Available at: <Available at: https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf >. Accessed on: June 20^th 2019.
» https://patentimages.storage.googleapis.com/57/77/eb/2834ccbfb7de7d/USPP22963.pdf

[4] CATUREGLI, L.; GAETANI, M.; VOLTERRANI, M.; MAGNI, S.; MINELLI, A.; BALDI, A.; BRANDANI, G.; MANCINI, M.; LENZI, A.; ORLANDINI, S.; LULLI, F.; BERTOLDI, C.; DUBBINI, M.; GROSSI, N. Normalized difference vegetation index versus dark green colour index to estimate nitrogen status on bermudagrass hybrid and tall fescue. International Journal of Remote Sensing, v.41, n.2, p.455-470, 2020. DOI: https://doi.org/10.1080/01431161.2019.1641762
» https://doi.org/10.1080/01431161.2019.1641762

[5] COLEHO, A.M. Adubação foliar em milho utilizando fertilizantes multinutrientes. Campo & Negócios, v.15, n.178, p.26-29, 2018.

[6] GAZOLA, R.P.D.; BUZETTI, S.; GAZOLA, R.N.; CASTILHO, R.M.M.; TEIXEIRA FILHO, M.C.M.; CELESTRINO, T.S. Nitrogen fertilization and glyphosate doses as growth regulators in Esmeralda grass. Revista Brasileira de Engenharia Agrícola e Ambiental, v.23, n.12, p.930-936, 2019. DOI: https://doi.org/10.1590/1807-1929/agriambi.v23n12p930-936
» https://doi.org/10.1590/1807-1929/agriambi.v23n12p930-936

[7] GAZOLA, R.P.D.; BUZETTI, S.; GAZOLA, R.N.; CASTILHO, R.M.M.; TEIXEIRA FILHO, M.C.M.; CELESTRINO, T.S.; DUPA, E. Nitrogen dose and type of herbicide used for growth regulation on the green coloration intensity of Emerald grass. Ciência Rural, v.46, n.6, p.984-990, 2016. DOI: http://dx.doi.org/10.1590/0103-8478cr20150276
» http://dx.doi.org/10.1590/0103-8478cr20150276

[8] GODOY, L.J.G.; VILLAS BÔAS, R.L.; BACKES, C.; SANTOS, A.J.M. Nutrição, Adubação e calagem para produção de gramas. Botucatu: FEPAF, 2012. 146p.

[9] KARCHER, D.E.; RICHARDSON, M.D. Quantifying turfgrass color using digital image analysis. Crop Science, v.43, p.943-951, 2003. DOI: https://doi.org/10.2135/cropsci2003.9430
» https://doi.org/10.2135/cropsci2003.9430

[10] KHANAL, S.; SCHWARTZ, B.M.; KIM, C.; ADHIKARI, J.; RAINVILLE, L.K.; AUCKLAND, S.A.; PETERSON, A.H. Cross-taxon application of sugarcane EST-SSR to genetic diversity analysis of bermudagrass (Cynodon spp.). Genetic Resources and Crop Evolution, n.64, p.2059-2070, 2017. DOI: https://doi.org/10.1007/s10722-017-0496-2
» https://doi.org/10.1007/s10722-017-0496-2

[11] LIMA, C.P.; BACKES, C.; FERNANDES, D.M.; SANTOS, A.J.M.; GODOY, L.J.G.; VILLAS BÔAS, R.L. Uso de índices de refletância das folhas para o nível de nitrogênio em grama-bermuda. Ciência Rural, v.42, n.9, p.1568-1574, 2012. DOI: http://dx.doi.org/10.1590/S0103-84782012005000062
» http://dx.doi.org/10.1590/S0103-84782012005000062

[12] LIMA, C.P.; BACKES, C.; SANTOS, A.J.M.; FERNANDES, D.M.; VILLAS BÔAS, R.L.; OLIVEIRA, M.R. Quantidade de nutrientes extraídos pela grama bermuda em função de doses de nitrogênio. Bioscience Journal, v.1, n.5, p.1432-1440, 2015. DOI: https://doi.org/10.14393/BJ-v31n5a2015-21967
» https://doi.org/10.14393/BJ-v31n5a2015-21967

[13] MATEUS, C.M.D.; TAVARES, A.R.T.; OLIVEIRA, M.R.; JACON, C.P.R.P.; SARTORI, M.M.P.; FERNANDES, D.M.; VILLAS-BÔAS, R.L. Influence of substrate base on sports field covered with bermuda grass. Ornamental Horticulture, v.23, n.3, p.319-328, 2017. DOI: https://doi.org/10.14295/oh.v23i3.1104
» https://doi.org/10.14295/oh.v23i3.1104

[14] OLIVEIRA, N.B.; OLIVEIRA, J.F.V.; SANTOS, P.L.F.; GAZOLA, R.P.D.; CASTILHO, R.M.M. Avaliação do estado nutricional de três gramados ornamentais em Ilha Solteira-SP: um estudo de caso. Revista LABVERDE, v.9, n.1, p.96-119, 2018. DOI: http://dx.doi.org/10.11606/issn.2179-2275.v9i1p96-119
» http://dx.doi.org/10.11606/issn.2179-2275.v9i1p96-119

[15] PETERSON, K.; SHONKWILER, A.K.; BREMER, D. Custom light box for digital image turfgrass analysis. In: K-State Turfgrass Research. Kansas: K-State University Publications, 2011. p.89-91.

[16] QUALLY GRAMA. Discovery Bermudagrass Less Mowing. 5p. Available at: <Available at: https://www.quallygrama.com.br/grama-discovery-lancamento.pdf >. Accessed on: June 20^th 2019.
» https://www.quallygrama.com.br/grama-discovery-lancamento.pdf

[17] SANTOS, P.L.F.; BARCELOS, J.P.Q.; CASTILHO, R.M.M. Diferentes substratos de um gramado ornamental para uso em telhados verdes. Periódico Técnico e Científico Cidades Verdes, v.4, n.10, p.81-94, 2016. DOI: http://dx.doi.org/10.17271/2317860441020161393
» http://dx.doi.org/10.17271/2317860441020161393

[18] SANTOS, P.L.F.; CASTILHO, R.M.M. Caracterização físico-química de diferentes substratos e sua influência no desenvolvimento da grama esmeralda. Tecnologia & Ciência Agropecuária, v.10, n.6, p.21-26, 2016.

[19] SANTOS, P.L.F.; CASTILHO, R.M.M. Relação entre teor de clorofila e nitrogênio foliar em grama esmeralda cultivada em substratos. Tecnologia & Ciência Agropecuária , v.9, n.2, p.51-54, 2015.

[20] SANTOS, P.L.F.; CASTILHO, R.M.M.; GAZOLA, R.P.D. Pigmentos fotossintéticos e sua correlação com nitrogênio e magnésio foliar em grama bermuda cultivada em substratos. Acta Iguazu, v.8, n.1, p.92-101, 2019.

[21] SANTOS, P.L.F.; CASTILHO, R.M.M. Resposta da grama esmeralda em função de diferentes fertilizantes e substratos. Cultura Agronômica, v.27, n.3, p.354-365, 2018a. DOI: https://doi.org/10.32929/2446-8355.2018v27n3p354-365
» https://doi.org/10.32929/2446-8355.2018v27n3p354-365

[22] SANTOS, P.L.F.; CASTILHO, R.M.M. Substrates in the development of a sports turfgrass “Tifton 419”. Ornamental Horticulture, v.24, n.4, p.138-144, 2018b. DOI: https://doi.org/10.14295/oh.v24i2.1155
» https://doi.org/10.14295/oh.v24i2.1155

[23] TAIZ, L.; ZEIGER, E.; MÜLLER, I.M.; MURPHY, A. Fisiologia e desenvolvimento vegetal. 6ed. Porto Alegre: Artmed, 2017. 858p.

pH	O.M.	P_resin	H+Al	K	Ca	Mg	BS	CEC	V%
CaCl₂	g dm^-3	mg dm^-3	_ _ _ _ _ _ _ _ _ _ _ _ _ mg dm^-3 _ _ _ _ _ _ _ _ _ _ _ _ _
5.6	20	108	14	2.9	26	8	37	50	73

Treatment	Days after installing the experiment
	1		2		3		4		5		6		7
	--------------------------- Scout CM1000 -----------------------
0 mL L^-1	191	a	193	b	195	c	184	c	182	c	185	c	186	c
50 mL L^-1	199	a	206	ab	235	b	279	b	305	b	302	b	304	b
75 mL L^-1	199	a	229	a	292	a	305	a	331	a	330	a	325	a
100 mL L^-1	201	a	222	a	292	a	303	a	322	ab	322	a	325	a
CVC	14		27		19		20		25		18		15
CV(%)	2.77		4.89		2.94		2.94		3.43		2.42		2.14
F	2.09^ns		7.34*		121.19**		156.55**		152.28**		287.08**		359.35**
Treatment	Days after installing the experiment
	8		9		10		11		12		13		14
	----------------------------- Scout CM1000 --------------------------
0 mL L^-1	180	c	186	c	185	b	188	c	189	c	182	b	186	b
50 mL L^-1	301	b	291	b	276	a	216	b	204	b	201	ab	202	ab
75 mL L^-1	323	a	312	a	289	a	242	a	218	a	216	a	211	a
100 mL L^-1	323	a	298	ab	279	a	240	a	213	ab	219	a	207	a
CVC	13		14		20		22		10		29		19
CV(%)	1.83		1.94		3.03		3.81		1.81		5.51		3.58
F	528.24**		364.7**		116.7**		27.16**		36.31**		6.77*		6.99*

Treatment	Days after installing the experiment
	1		2		3		4		5		6		7
	------------------------------- Scout TCM 500 -----------------------------------
0 mL L^-1	6.6	a	6.7	b	6.7	b	6.7	c	6.7	b	6.6	c	6.4	c
50 mL L^-1	6.7	a	6.9	b	7.0	b	7.3	b	7.4	a	7.5	b	7.4	b
75 mL L^-1	6.9	a	7.5	a	7.6	a	8.0	a	8.0	a	8.1	a	8.3	a
100 mL L^-1	6.9	a	7.5	a	7.6	a	7.9	a	7.9	a	8.1	a	8.2	a
CVC	0.9		0.5		0.6		0.5		0.7		0.6		0.6
CV(%)	4.85		2.55		3.11		2.75		3.59		2.97		3.24
F	0.58^ns		15.83**		11.47*		25.23**		15.77**		30.36**		38.93**
Treatment	Days after installing the experiment
	8		9		10		11		12		13		14
	------------------------------- Scout TCM 500 -----------------------------------
0 mL L^-1	6.5	c	6.3	c	6.3	c	6.2	c	6.2	c	6.4	b	6.2	b
50 mL L^-1	7.4	b	7.3	b	7.2	b	7.1	b	7.1	b	7.1	a	6.9	a
75 mL L^-1	8.2	a	8.0	a	7.9	a	7.9	a	7.5	a	7.3	a	7.2	a
100 mL L^-1	8.2	a	8.0	a	8.0	a	7.7	a	7.5	a	7.4	a	7.1	a
CVC	0.6		0.5		0.4		0.5		0.3		0.6		0.3
CV(%)	3.01		2.50		2.09		2.59		1.82		3.20		1.88
F	39.72**		59.15**		79.29**		47.68**		65.92**		11.56**		35.07**

Treatment	7 days after installing the experiment
	Green (G)		Hue (H)		Saturation (S)		Brightness (B)		Dark Green (DGCI)
	---		degrees ( º )		%		%		---
0 mL L^-1	98	b	72	b	40	ab	40	b	0.47	b
50 mL L^-1	124	a	86	a	51	a	44	a	0.49	b
75 mL L^-1	131	a	92	a	39	b	42	ab	0.58	a
100 mL L^-1	131	a	93	a	40	ab	42	ab	0.57	a
CVC	10		7		11		3		0.05
CV(%)	2.96		3.15		9.63		2.64		3.27
F	58.38**		36.27**		5.39*		6.98*		30.88**
Treatment	14 days after installing the experiment
	Green (G)		Hue (H)		Saturation (S)		Brightness (B)		Dark Green (DGCI)
	---		degrees ( º )		%		%		---
0 mL L^-1	88	c	47	b	17	b	36	b	0.42	a
50 mL L^-1	109	b	58	ab	25	ab	37	ab	0.45	a
75 mL L^-1	118	a	64	a	32	a	38	a	0.46	a
100 mL L^-1	119	a	68	a	33	a	38	a	0.47	a
CVC	5		15		10		2		0.09
CV(%)	1.91		9.70		15.09		1.68		7.36
F	140.17**		7.61**		9.61*		8.08**		1.63^ns

Treatment	days after installing the experiment
	1		2		3		4		5		6		7
	------------------------------------- mm ------------------------------------
0 mL L^-1	15.1	a	15.1	a	15.4	a	15.2	b	15.3	c	15.5	b	15.6	c
50 mL L^-1	15.4	a	15.5	a	15.1	a	15.4	b	15.7	b	15.9	b	16.2	b
75 mL L^-1	15.2	a	15.2	a	15.2	a	15.9	a	16.1	a	16.4	a	16.7	a
100 mL L^-1	14.8	a	15.2	a	15.2	a	15.8	a	16.1	a	16.5	a	16.7	a
CVC	0.9		1.0		0.6		0.3		0.3		0.4		0.5
CV(%)	2.20		2.42		1.49		0.79		0.68		1.05		1.20
F	1.75^ns		0.53^ns		0.83^ns		22.37**		36.62**		23.65**		21.59**
Treatment	days after installing the experiment
	8		9		10		11		12		13		14
	----------------------------------- mm ---------------------------------------
0 mL L^-1	15.7	c	16.0	c	16.3	c	16.7	c	17.1	c	17.3	c	17.8	c
50 mL L^-1	16.5	b	16.7	b	16.9	b	17.4	b	18.3	b	18.5	b	19.2	b
75 mL L^-1	17.2	a	17.5	a	18.3	a	18.6	a	19.0	ab	19.7	a	20.3	a
100 mL L^-1	17.2	a	17.5	a	18.3	a	18.6	a	19.3	a	19.6	a	20.1	a
CVC	0.5		0.6		0.5		0.5		0.9		0.6		0.6
CV(%)	1.20		1.31		1.12		1.12		1.82		1.21		1.2
F	40.41**		33.01**		76.17**		67.50**		26.55**		71.07**		70.50**

Brasil

Brasil

Foliar fertilization in Bermuda grass Discovery^TM

Adubação foliar em grama Bermuda Discovery^TM

Abstract

Resumo

Introduction

Material and Methods

Results and Discussions

Conclusions

Acknowledgements

References

Publication Dates

History

Treatment	15 days after installing the experiment
Treatment	----------------- g m^-2 ---------------
0 mL L^-1	2.03 c
50 mL L^-1	3.52 b
75 mL L^-1	4.60 a
100 mL L^-1	4.70 a
CVC	0.70
CV(%)	7.4
F	63.27**

Brasil

Brasil

Foliar fertilization in Bermuda grass DiscoveryTM

Adubação foliar em grama Bermuda DiscoveryTM

Abstract

Resumo

Introduction

Material and Methods

Results and Discussions

Conclusions

Acknowledgements

References

Publication Dates

History

Foliar fertilization in Bermuda grass Discovery^TM

Adubação foliar em grama Bermuda Discovery^TM