Production of yellow passion fruit seedlings as a function of alternative growing media and controlled-release fertilizer

Guilherme, João Paulo Maia; Andrade Neto, Romeu de Carvalho; Carvalho, Pedro Henrique da Silva; Araújo, James Maciel de; Muniz, Paulo Sérgio Braña

doi:10.1590/0034-737X2024710006

ABSTRACT

With the objective of evaluate the use of residues as growing media for the yellow passion fruit seedlings, a randomized block experiment was carried out with treatments distributed in a 2 × 21 factorial scheme corresponding to fertilizer management (presence and absence of controlled-release fertilizer), and combination of growing media from five local agro-industrial wastes (bark of cupuaçu fruit, almond shell of castanha-do-brasil, lumps of acerola fruit, lumps of cajá fruit, and lumps of açaí fruit) and a commercial growing media, which tested pure and was combined in a 1:1 ratio. The variables measured were the seedling height; stem diameter; height: stem diameter ratio; number of leaves; shoot, root, and total dry matter; and Dickson quality index. The dates were submitted to univariate and multivariate analyzes. The pairwise combination of growing medias produced from the bark of cupuaçu fruit, almond shell of castanha-do-brasil, lumps of acerola fruit, lumps of cajá fruit, lumps of açaí fruit, and commercial growing media in a proportion of 1:1 and with the use of controlled-release fertilizer constitute an alternative for other growing medias in the production of yellow passion fruit seedlings.

Keywords
Agro-industrial wastes; fertilization management; Passiflora edulis Sims.; seedling quality

INTRODUCTION

Numerous studies have aimed to provide information on the potential of waste that can be utilized as a growing media in the production of seedlings (Silva et al., 2018Silva NM, Souza SLG, Uchôa TL, Almeida WA, Araújo Neto SE & Ferreira RLF (2018) Qualidade de mudas orgânicas de maracujazeiro amarelo produzidas com substratos alternativos. Agropecuária Científica no Semiárido, 14:96-102.; Monaco et al., 2020Monaco PAVL, Vieira JC, Colombo JN, Krause MR, Vieira GHS & Almeida KM (2020) Use of agricultural waste material as an alternative growing media in cabbage seedling production and development. Emirates Journal of Food and Agriculture, 32:131-139.; Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.; Bustamante et al., 2021Bustamante MA, Gomis MP, Pérez-Murcia MD, Gangi D, Ceglie FG, Paredes C, Pérez-Espinosa A, Bernal MP & Moral R (2021) Use of livestock waste composts as nursery growing media: Effect of a washing pre-treatment. Scientia Horticulturae, 281:109954.), with the objective of minimizing the environmental impacts caused by the incorrect disposal (Krause et al., 2017Krause MR, Monaco PAVL, Haddade IR, Meneghelli LAM & Souza TD (2017) Aproveitamento de resíduos agrícolas na composição de substratos para produção de mudas de tomateiro. Horticultura Brasileira, 35:305-310.).

During the formation phase, the interaction between fertilization and growing media properties influences the morphophysiological characteristics of seedlings (Mariotti et al., 2020Mariotti B, Martini S, Raddi S, Tani A, Jacobs DF, Oliet JA & Maltoni A (2020) Coconut coir as a sustainable nursery growing media for seedling production of the ecologically diverse Quercus species. Forests, 11:04-07.). Although most growing medias conform to the standards established by legislation, the nutrient content of the material is insufficient to meet the requirements of seedlings for successful planting (Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.; Silva et al., 2020Silva PCR, Paiva PEB, Charlo HCO & Coelho VPM (2020) Slow Release Fertilizers or Fertigation for Sugarcane and Passion Fruit Seedlings? Agronomic Performance and Costs. Journal of Soil Science and Plant Nutrition, 20:2175-2181.).

Hence, nutritional supplementation is necessary during growing media formulation, either by fertigation (Madrid-Aispuro et al., 2020Madrid-Aispuro RE, Prieto-Ruíz JA, Aldrete A, Hernández-Díaz JC, Wehenkel C, Chávez-Simental JA & Mexal JG (2020) Alternative growing medias and fertilization doses in the production of Pinus cembroides Zucc. in nursery. Forests, 11:01-13.) or conventional fertilizer application. Fertilization with conventional fertilizers can results in greater nutrient losses through leaching and volatilization (Vejan et al., 2021Vejan P, Khadiran T, Abdullah R & Ahmad N (2021) Controlled release fertilizer: A review on developments, applications and potential in agriculture. Journal of Controlled Release, 339:321-334.), discomfort for nursery workers, and the creation of low-quality seedlings, all of which reflect the cost of production.

As an alternative to conventional fertilizer application, controlled-release fertilizers represents a promising technology for the production of passion fruit seedlings (Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.; Silva et al., 2020Silva PCR, Paiva PEB, Charlo HCO & Coelho VPM (2020) Slow Release Fertilizers or Fertigation for Sugarcane and Passion Fruit Seedlings? Agronomic Performance and Costs. Journal of Soil Science and Plant Nutrition, 20:2175-2181.). This method presents the advantage that the fertilizer is applied to the growing media only during the preparation phase (Smiderle et al., 2020Smiderle OJ, Souza ADG & Menegatti RD (2020) Controlled-Release Fertilizer in the Production of Seedlings of Anonna cacans Warm. Journal of Agricultural Studies, 8:125-133.). Although expensive, this technology decreases production costs, production time, labor required, and operational expenses; In addition, it optimizes space utilization, water use, and energy requirements (Gibson et al., 2019Gibson EL, Gonçalves EDO, Ramalho A, Santos D, Araújo EF, Vinicius M & Caldeira W (2019) Controlled-Release Fertilizer on Growth of Melanoxylon brauna Schott Seedlings. Floresta e Ambiente, 26:01-07.).

The objective with study was to determine the influence of alternative growing medias and controlled-release fertilizer on the production of yellow passion fruit seedlings.

MATERIAL AND METHODS

From December 2017 to January 2018, the experiment was conducted at a nursery with 50% shading in the experimental field of Embrapa Acre in Rio Branco, Acre State, Brazilian Amazon (11°58’35″ S, 68°17’56″ W, altitude 159 m). Inside the nursery the maximum and minimum temperatures were 31.8 °C and 21.4 °C, respectively; and the relative humidity was 88.7%.

For the formulation of the growing medias, a commercial growing media based on pine bark (Com) and five agro-industrial residues, namely lumps of açaí fruit (Al); lumps of cajá fruit (Lcf); almond shell of castanha-do-brasil (Ascb); bark of cupuaçu fruit (Bcf); and lumps of acerola fruit (Laf) were used. After collection, the materials were dried in the sun for a week and then ground using a disintegrator (model B-611 and Maqtron®) with a 10 mm diameter sieve. Subsequently, they were combined in proportions of 1:1 (v/v ratio) using the combinatorial analysis of ‘n’ distinct elements, taken p = 2 to p = 2, yielding 15 combinations, plus the six pure growing media, resulting in 21 growing medias (T1: Bcf + Ascb; T2: Bcf + Laf; T3: Bcf + Lcf; T4: Bcf + Al; T5: Bcf + Com; T6: Ascb + Laf; T7: Ascb + Lcf; T8: Ascb + Al; T9: Ascb + Com; T10: Laf + Lcf; T11: Laf + Al; T12: Laf + Com; T3: Lcf + Al; T14: Lcf + Com; T15: Al + Com; T16: Bcf; T17: Ascb; T18: Laf; T19: Lcf; T20: Al and; T21: Com).

A randomized block design was used with three replicates and seven plants per plot, in a 21 × 2 factorial scheme, consisting of 21 growing medias, with and without controlled-release fertilizer. Table 1 lists the physical and chemical characteristics of the growing medias.

Thumbnail

Table 1
physical and chemical attributes of the growing medias and mixtures obtained from agro-industrial waste

For fertilizer application, 10 kg m^-3 of Basacote® Mini 3 M controlled-release fertilizer with an N-P-K formulation of 13-6-16, macro-and micronutrient profile of Mg: 1.4, S:10, Cu: 0.05, Fe: 0.26, Mn: 0.06, and Mo: 0.015, and a nutrient release duration of up to three months was used.

Polyethylene (disposable) pots with 300 mL capacity were utilized as growing media containers. Two seeds of the passion fruit ‘BRS Gigante Amarelo’ were used per container for sowing purposes. One day after emergence of the first pair of cotyledonary leaves, thinning was performed and one plant was left per container. Micro-sprinkler irrigation system was used to maintain the field capacity of the growing medias. The experimental area was covered with a transparent plastic canvas suited for greenhouses to prevent excess moisture from precipitation entering the area.

On day 54 after sowing, the following characteristics were measured: seedling height (H; cm), measured from the neck of the plant to the petiole of the youngest leaf with a graduated ruler; stem diameter (SD; mm), measured from the neck of the plant to 1 cm above the growing media with a digital caliper; height: stem diameter ratio (HSD); and number of leaves (NL). Subsequently, the seedlings were separated into shoots and roots, packed into raft paper bags, oven-dried at 65 °C until constant mass is achieved, and weighed on a digital scale to determine the following variables: shoot dry mass (SDM; g), root dry mass (RDM; g), and total dry mass (TDM; g).

The seedling quality was determined using the Dickson quality index (DQI) according to Equation (1) proposed by Dickson et al. (1960)Dickson A, Leaf AL & Hosner JF (1960) Quality appraisal of white spruce and white pine seedling stock in nurseries. The Forestry Chronicle, 36:10-13.:

DQI = \frac{TDM (g)}{(\frac{H (cm)}{SD (mm)}) + (\frac{SDM (g)}{RDM (g)})}

(1)

The analysis of variance was performed and the means of the growing medias were compared using the Scott–Knott test, and the fertilization means were compared using the Tukey test, both at a 5% probability.

The Pearson correlation coefficients were calculated among the biometric variables of the seedlings, the chemical and physical attributes of the substrates, and between these and those. These coefficients were visually represented by a correlation network, where closer and thicker nodes indicate a stronger correlation, with green representing positive correlations and red representing negative correlations. (Oliveira & Oliveira, 2021Oliveira JTD & Oliveira RAD (2021) Path analysis of physical attributes of chayote fruit. Engenharia Agrícola, 41:468-474.).

The data referring to the eight variables were submitted to multivariate analysis to obtain the dissimilarity matrix based on the Euclidean Mean Distance and, subsequently, the Unweighted Pair Group Method with Arithmetic Mean (UPGMA) was applied in order to group the treatments that were similar. Univariate analyses, as well as the correlation network, were performed using the Rbio software (Bhering, 2017Bhering LL (2017) Rbio: A tool for biometric and statistical analysis using the R platform. Crop Breeding and Applied Biotechnology, 17:187-190.) and multivariate analyses were performed using Genes software (Cruz, 2013Cruz CD (2013) Genes - a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35:271-276.).

RESULTS AND DISCUSSION

There was a significant interaction between the G x F factors for all biometric variables of yellow passion fruit seedlings evaluated (Table 2).

Thumbnail

Table 2
Summary of variance analysis of seedling height (H), stem diameter (SD), height: stem diameter ratio (HSD), number of leaves (NL), shoot dry mass (SDM; g), root dry mass (RDM; g), total dry mass (TDM) and Dickson quality index (DQI) of yellow passion fruit seedlings produced in growing medias, with and without controlled-release fertilizer

The H, SD, HSD, and NL of the yellow passion fruit seedlings were higher in fertilized growing medias than those in the unfertilized growing medias (Figure 1A to 1D).

Figure 1
Mean values for seedling height – H (A), stem diameter - SD (B), height: stem diameter – HSD (C) and number of leaves – NL (D) of yellow passion fruit seedlings produced as a function of alternative growing media and controlled-release fertilizer.Notes: Bars with the same lowercase letters do not differ in substrate composition among themselves by Scott-Knott’s test at p < 0.05 probability. Bars with the same capital letters do not differ in terms of presence and absence of fertilization, by Tukey’s test with probability p < 0.05.

In fertilized growing medias, the combinations of Bcf + Laf, Bcf + Lcf, Bcf + Al, Bcf + Com, Laf + Lcf, Laf + Al, Lcf + Com and Al + Com caused the seedlings to attain greater H (Figure 1A). The heights of the seedlings produced in the treatments exceeded the values reported in the literature (Silva et al., 2020Silva PCR, Paiva PEB, Charlo HCO & Coelho VPM (2020) Slow Release Fertilizers or Fertigation for Sugarcane and Passion Fruit Seedlings? Agronomic Performance and Costs. Journal of Soil Science and Plant Nutrition, 20:2175-2181.; Cordeiro et al., 2019Cordeiro KV, Costa NA, Andrade HAF, Oliveira-Neto ED, Rocha BR, Farias MNA, Albano FG, Furtado MB & Silva-Matos RRS (2019) Inclusion of Babassu Decomposed Stem Growing medias on the Pattern of the Vegetative Growth of Passion Fruit Seedlings. Communications in Soil Science and Plant Analysis, 50:2777-2786.). According to Junghans et al. (2017)Junghans TG, Rosa RCC & Girardi EA (2017) Produção de mudas de maracujazeiro. In: Junghans TG & Jesus ON (Eds.) Maracujá: do cultivo à comercialização. Brasília, Embrapa Mandioca e Fruticultura. p.101-114., yellow passion fruit seedlings are suitable for planting at 15–30 cm height, which would accredit the Laf + Com growing media with a potential use in the production of passion fruit seedlings without fertilization. This finding is pertinent for those nurseries where seedlings need to be produced at the lowest possible cost.

Higher mean values for SD were obtained for the Bcf + Laf, Bcf + Lcf, Bcf + Al, Bcf + Com, Ascb+Laf, Laf + Lcf, Laf + Al, Laf + Com, Lcf and Com (Figure 1B). The stem diameters of the seedlings produced on the best growing medias exceeded those specified by Silva et al. (2020)Silva PCR, Paiva PEB, Charlo HCO & Coelho VPM (2020) Slow Release Fertilizers or Fertigation for Sugarcane and Passion Fruit Seedlings? Agronomic Performance and Costs. Journal of Soil Science and Plant Nutrition, 20:2175-2181..

The growing medias Bcf + Laf, Bcf + Lcf, Bcf + Al, Bcf + Com, Ascb + Com, Laf + Lcf, Laf + Al, Lcf + Com, Al + Com, Bcf, Lcf and Com, all in the presence of fertilizer, caused the seedlings to attain greater HSD (Figures 1C). Passion fruit seedlings with HSD values between 13.60 and 17.42 at 54 days after sowing were suitable for field planting. However, as with forest species, HSD may vary depending on several factors such as growing media, fertilization, and seedling age (Faria et al., 2019Faria JCT, Lopes DA, Lyra GB, Melo HC & Melo LA (2019) Manejo da densidade de plantas durante a produção de mudas em viveiro. Ciência Florestal, 29:1187-1198.).

Higher mean values for NL were obtained for the Bcf + Ascb, Bcf + Laf, Bcf + Lcf, Bcf + Al, Bcf + Com, Ascb + Com, Laf + Lcf, Laf + Al, Laf + Com, Lcf + Com, Al + Com, Bcf, Al and Com (Figure 1D). Thus, the results of the study outweighed those reported by Silva et al. (2020)Silva PCR, Paiva PEB, Charlo HCO & Coelho VPM (2020) Slow Release Fertilizers or Fertigation for Sugarcane and Passion Fruit Seedlings? Agronomic Performance and Costs. Journal of Soil Science and Plant Nutrition, 20:2175-2181..

In the presence of fertilizer, the seedlings had higher RDM, SDM, TDM and DQI than without fertilizer (Figures 2A to 2D).

Figure 2
Mean values for shoot dry mass – SDM (A), root dry mass – RDM (B), total dry mass – TDM (C) and Dickson quality index – DQI (D) of yellow passion fruit seedlings produced as a function of alternative growing media and controlled-release fertilizer.Notes: Bars with the same lowercase letters do not differ in substrate composition among themselves by Scott-Knott’s test at p < 0.05 probability. Bars with the same capital letters do not differ in terms of presence and absence of fertilization, by Tukey’s test with probability p < 0.05.

The seedlings showed increased SDM in the Laf + Lcf, Al + Com and Com growing medias (Figure 2A). RDM of passion fruit seedlings were higher in the growing medias Bcf + Ascb, Bcf + Laf, Bcf + Lcf, Bcf + Al, Ascb + Laf Lcf + Com and Com (Figure 2B). Concerning to TDM, Bcf + Laf, Bcf + Lcf, Bcf + Al, Bcf + Com, Ascb + Laf, Laf + Lcf, Laf + Al, Laf + Com, Lcf + Com, Al + Com and Lcf caused the seedlings to attain greater values (Figure 2C). Seedlings produced on the Ascb + Laf and Com growing medias acquired the greatest DQI values (Figure 2D).

The values of dry biomass of the seedlings produced on the growing medias that stood out in this study were comparable to or exceeded those described in the literature (Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.; Cordeiro et al., 2019Cordeiro KV, Costa NA, Andrade HAF, Oliveira-Neto ED, Rocha BR, Farias MNA, Albano FG, Furtado MB & Silva-Matos RRS (2019) Inclusion of Babassu Decomposed Stem Growing medias on the Pattern of the Vegetative Growth of Passion Fruit Seedlings. Communications in Soil Science and Plant Analysis, 50:2777-2786.). However, in certain cases, they were lower which could be attributed to the differences in the cultivars and management practices adopted during seedling production (Mendonça et al., 2021Mendonça A, Natale W, Sousa GG & Silva FB (2021) Morphophysiology and nutrition of yellow passion fruit seedlings grown in growing medias based on carnaúba palm bagana. Revista Brasileira de Ciências Agrárias, 16:01-07.).

The lowest values may have resulted from the RDM that contributed the least to TDM, since the high availability of nutrients from growing medias and fertilizer reduced the need of plants to further expand their root systems (Wang et al., 2018Wang P, Yang Y, Mou P, Zhao Q & Li Y (2018) Local root growth and death are mediated by contrasts in nutrient availability and root quantity between soil patches. Proceedings of the Royal Society B: Biological Sciences, 285:20180699.).

The DQI values are variable for yellow passion fruit seedlings in research because they depend on seedling production management practices and factors, such as the environment, growing media, mineral nutrition, irrigation technique, quality of water used in irrigation, seedling age, cultivar, sowing depth, containers, plant health, and the interaction of environmental factors and genotype. Mendonça et al. (2021)Mendonça A, Natale W, Sousa GG & Silva FB (2021) Morphophysiology and nutrition of yellow passion fruit seedlings grown in growing medias based on carnaúba palm bagana. Revista Brasileira de Ciências Agrárias, 16:01-07. obtained a DQI of 0.33 when using soil and carnauba bagasse (1:1) as growing media; Silva et al. (2018)Silva NM, Souza SLG, Uchôa TL, Almeida WA, Araújo Neto SE & Ferreira RLF (2018) Qualidade de mudas orgânicas de maracujazeiro amarelo produzidas com substratos alternativos. Agropecuária Científica no Semiárido, 14:96-102. reported a DQI value of 0.20 in growing media whose composition included carbonized rice husk and decomposed stem of Ceiba pentandra L.; Muniz et al. (2020)Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10. discovered maximum DQI values of 0.25, 0.20 and 0.24 in growing media composed of acerola lumps, growing media made of almond shell of castanha-do-brasil, and commercial growing media, respectively, all the three were supplemented with 12 kg m^-3 of controlled-release fertilizer.

There was no correlation observed between the biometric characteristics of fertilized and non-fertilized seedlings (Figure 3). However, overall, both the seedlings grown in the substrate with controlled-release fertilizer and those without it exhibited strong, significant, and positive correlations. In general, the chemical and physical attributes of the substrates did not show significant correlations with the biometric characteristics of passion fruit seedlings, except for phosphorus (P), which showed a moderate and positive correlation with SDM and NL. Therefore, the results of this study reinforce that the highest-rated substrates can be used regardless of their specific attributes, since as they receive proper nutritional management, as this leads to the seedlings exhibiting desirable characteristics for planting.

Figure 3
Correlation networks between the biometric characteristics of fertilized and non-fertilized passion fruit seedlings, between the chemical and physical attributes of the substrates, and between the chemical and physical attributes of the substrates and the biometric characteristics of the seedlings.

Considering that only the growing medias that received the controlled release fertilizer led the seedlings to reach minimum standards to be taken to the field, it was applied cluster analysis. From the dendrogram obtained by the UPGMA method, it was verified the formation of four groups of growing medias (Figure 4).

Figure 4
Dendrogram generated by UPGMA method from the dissimilarities through the Euclidean Mean Distance among 21 growing media containing controlled-release fertilizer, based in eight features of seedlings passion fruit.

The first group was formed by Ascb + Al and Ascb growing medias; the second by Lcf + Al, Ascb + Lcf, Laf, Bcf + Ascb and by Al; the third by the growing media Ascb + Laf; and the fourth, with 61.9% of similar growing medias, by Al + Com, Laf + Com, Ascb + Com, Laf + Al, Bcf, Lcf, Com, Bcf + Al, Bcf + Com, Laf + Lcf, Bcf + Laf, Bcf + Lcf and Lcf + Com. The cophenetic correlation coefficient was 0.73, indicating an adequate adjustment of the UPGMA clustering method to verify the similarity between treatments (Streck et al., 2017Streck EA, Aguiar GA, Magalhães Júnior AM, Facchinello PHK & Oliveira AC (2017) Variabilidade fenotípica de genótipos de arroz irrigado via análise multivariada. Revista Ciência Agronômica, 48:101-109.).

Therefore, more than half of the evaluated growing medias are like the commercial one, thus constituting viable alternatives to produce yellow passion fruit seedlings. Silva et al. (2022)Silva LN, Lima LKS, Santos IS, Sampaio SR & Jesus ON (2022) Multivariate strategies for selection of organic growing media to produce yellow passion fruit seedlings. Organic Agriculture, 12:445-459. verified that the cluster analysis was efficient to select alternative growing medias, with a reduction of up to 60% of the commercial one in their mixtures, to produce E. edulis seedlings.

Owing to their physicochemical properties (Table 1) and the application of fertilizer, the Bcf + Laf, Bcf + Lcf, Bcf + Al, Bcf + Com, Ascb + Laf, Laf + Al, Laf + Com, Lcf + Com, Lcf, and Com growing media combinations were responsible for the seedlings attaining better biometric characteristics (Figures 1, 2 and 4).

As established by Ingram (2014)Ingram DL (2014) Understanding Soilless Media Test Results and Their Implications on Nursery and Greenhouse Crop Management. Agriculture and Natural Resources Publications, 161., Bcf + Laf, Bcf + Al, and Lcf + Com possessed pH in the optimal range (5.7–6.5); Ascb + Laf and Com in the acceptable range (5.0–5.6); Bcf + Lcf, Bcf + Com, Laf + Com, and Laf in the higher range (6.6–7.0); while Laf + Al possessed pH in the lower range (< 5.0). However, in the case of Laf + Al, the levels of macro nutrients were not compromised. The high pH of growing media can be adjusted by applying sulfuric acid (Massa et al., 2018Massa D, Malorgio F, Lazzereschi S, Carmassi G, Prisa D & Burchi G (2018) Evaluation of two green composts for peat substitution in geranium (Pelargonium zonale L.) cultivation: Effect on plant growth, quality, nutrition, and photosynthesis. Scientia Horticulturae, 228:213-221.) or by using other low-pH components. Similarly, the low pH of growing medias can be corrected with limestone application (Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.) or with higher pH mixtures. Passion fruit is sensitive to electrical conductivity; seeds do not germinate and plants do not grow or produce properly in locations where the electrical conductivity of the soil saturation extract is greater than 1.3 dS m^-1 (Cavalcante et al., 2009Cavalcante LF, Sousa GG, Gondim SC, Figueiredo FL, Cavalcante ÍHL & Diniz AA (2009) Crescimento inicial do maracujazeiro amarelo manejado em dois substratos irrigados com água salina. Irriga, 14:504-517.). Therefore, the growing medias that present electrical conductivity between 0.3 and 1.2 dS m^-1 are considered possessing an acceptable range (Abad et al., 2001Abad M, Noguera P & Burés S (2001) National inventory of organic wastes for use as growing media for ornamental potted plant production: case study in Spain. Bioresource Technology, 77:197-200.).

The macro and micronutrient content of the growing medias in the current study exceeded the optimal values proposed by Ingram (2014)Ingram DL (2014) Understanding Soilless Media Test Results and Their Implications on Nursery and Greenhouse Crop Management. Agriculture and Natural Resources Publications, 161.. The contents of N, P, K, and Mg were higher than those determined by Cordeiro et al. (2019)Cordeiro KV, Costa NA, Andrade HAF, Oliveira-Neto ED, Rocha BR, Farias MNA, Albano FG, Furtado MB & Silva-Matos RRS (2019) Inclusion of Babassu Decomposed Stem Growing medias on the Pattern of the Vegetative Growth of Passion Fruit Seedlings. Communications in Soil Science and Plant Analysis, 50:2777-2786., in the growing media formulated with 80% decomposed babassu stem + 20% soil and sand (1:1) as well as in the commercial growing media, both of which are recommended for the production of yellow passion fruit seedlings. The cation exchange capacity values of the growing medias used in our study were superior to that determined by Costa et al. (2018)Costa FM, Anjos GL, Camilo GBM, Oliveira UC, Souza GS & Santos AR (2018) Produção de mudas de maracujazeiro amarelo em diferentes composições de substrato e ambiente. Revista de Ciências Agrárias, 41:138-146. and lower than the values established by Méndez et al. (2015)Méndez A, Paz-Ferreiro J, Gil E & Gascó G (2015) The effect of paper sludge and biochar addition on brown peat and coir based growing media properties. Scientia Horticulturae, 193:225-230.. This was probably because of the particle size of the growing medias, (Altland et al., 2014Altland JE, Locke JC & Krause CR (2014) Influence of pine bark particle size and pH on cation exchange capacity. HortTechnology, 24:554-559.) which did not impair the performance of the growing medias due to the fertilization carried out or other chemical and physical characteristics presented.

Bcf + Laf, Ascb + Laf, Laf + Al, and Laf + Com growing media usages achieved adequate C/N ratios (Gavilanes-Terán et al., 2017Gavilanes-Terán I, Jara-Samaniego J, Idrovo-Novillo J, Bustamante M, Pérez-Murcia MD, Pérez-Espinosa A, López M & Paredes C (2017) Agroindustrial compost as a peat alternative in the horticultural industry of Ecuador. Journal of Environmental Management, 186:79-87.), probably due to the presence of LAF. The C/N ratio of the other growing medias may have been offset by the addition of the controlled-release fertilizer that contained 13% N, which was high enough to prevent competition between seedlings and microorganisms (González-Orozco et al., 2018González-Orozco MM, Prieto-Ruíz JA, Aldrete A, Hernández-Díaz JC, Chávez-Simental JA & Rodríguez-Laguna R (2018) Nursery production of Pinus engelmannii Carr. with growing medias based on fresh sawdust. Forests, 9:01-15.). The commercial growing media, which is generally recommended for growing yellow passion fruit species, has a higher C/N ratio than most alternative growing medias; however, the growing media has been found suitable for the production of passion fruit seedlings. In this regard, it is perceived that this characteristic cannot be applied universally, because growing medias with higher C/N ratios than the recommended value do not always affect the production of vegetable seedlings (Nieto et al., 2016Nieto A, Gascó G, Paz-Ferreiro J, Fernández JM, Plaza C & Méndez A (2016) The effect of pruning waste and biochar addition on brown peat based growing media properties. Scientia Horticulturae, 199:142-148.).

Growing medias that present favorable physical characteristics such as bulk, volumetric, and particle densities, porosity, water holding capacity, and total porosity typically result in better seedling formation (Zorzeto et al., 2014Zorzeto TQ, Dechen SCF, Abreu MF & Fernandes Júnior F (2014) Caracterização física de substratos para plantas. Bragantia, 73:300-311.).

Suitable growing medias must have a density of less than 400 kg m^-3 (Abad et al. 2001Abad M, Noguera P & Burés S (2001) National inventory of organic wastes for use as growing media for ornamental potted plant production: case study in Spain. Bioresource Technology, 77:197-200.). Bcf + Al and Laf + Al possessed higher values; however, other desirable characteristics and resultant positive effects on seedling production overrode this limitation. Hence, it can be suggested that dry density is not a limiting factor and should be defined according to species (Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.). The values reported in the literature vary widely depending on the species and growing media, without compromising seedling quality (Mota et al., 2018Mota CS, Silva FG, Dornelles P, Freiberger MB, Reis DN & Mendes GC (2018) Parameters of Physiology, Nutrition and Quality of Eugenia dysenterica DC Seedlings Grown in Organic Growing medias from the Agricultural Industry. Journal of Agricultural Science, 10:73-84.; Neres et al., 2019Neres YXC, Azevedo GTOS, Souza AM, Azevedo GB & Teodoro PE (2019) Effect of the hydrogel incorporation on different growing medias on the rooting and quality of clonal Eucalyptus seedlings. Scientia Forestalis, 47:336-345.).

Bcf + Laf, Bcf + Lcf, Bcf + Al, and Lcf showed water retention capacities in the indicated ranges (Méndez et al., 2015Méndez A, Paz-Ferreiro J, Gil E & Gascó G (2015) The effect of paper sludge and biochar addition on brown peat and coir based growing media properties. Scientia Horticulturae, 193:225-230.; Noguera et al., 2003Noguera P, Abad M, Puchades R, Maquieira A & Noguera V (2003) Influence of particle size on physical and chemical properties of coconut coir dust as container medium. Communications in soil science and plant analysis, 34:593-605.). Nevertheless, growing medias with lower water retention capacities can be used if a strategy is adopted to ensure water availability for plants throughout the day.

Therefore, it can be perceived that renewable growing medias associated with fertilization provide a viable alternative to commercial growing medias for the production of yellow passion fruit seedlings from a technical point of view.

Several studies have shown the growth and development of yellow passion fruit seedlings as a function of growing medias associated with fertilization (Muniz et al., 2020Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.). Therefore, it is clear that the growing medias presenting considerable physicochemical characteristics also need nutritional supplementation, including commercial ones.

It is important to note that the fertilizer used had a release duration of three months. However, as the seedlings were evaluated by day 54, it is possible to reduce the amount of fertilizer in the first cover fertilization, hence, amortizing the initial cost of implantation. The fact that these growing medias can be used in larger containers associated with a longer stay in the nursery to produce a taller seedling (“mudão”-type, where the seedlings are above 90 cm tall) as a cultural strategy to mitigate the effect of diseases in the field is also worthy of mention.

CONCLUSIONS

The pairwise combination of growing medias produced from the bark of cupuaçu fruit, almond shell of castanha-do-brasil, lumps of acerola fruit, lumps of cajá fruit, lumps of açaí fruit, and commercial growing media in a proportion of 1:1 and with the use of controlled-release fertilizer constitute an alternative for other growing medias in the production of yellow passion fruit seedlings.

ACKNOWLEDGEMENTS, FINANCIAL SUPPORT AND FULL DISCLOSURE

To National Council for Scientific and Technological Development (CNPq) for securing Scholarship of Productivity in Technology Development and Innovative Extension (DT) to the second author (Process 313552/2017-7).

1
This article is part of the Master Dissertation of the first author.

REFERENCES

Abad M, Noguera P & Burés S (2001) National inventory of organic wastes for use as growing media for ornamental potted plant production: case study in Spain. Bioresource Technology, 77:197-200.
Altland JE, Locke JC & Krause CR (2014) Influence of pine bark particle size and pH on cation exchange capacity. HortTechnology, 24:554-559.
Bhering LL (2017) Rbio: A tool for biometric and statistical analysis using the R platform. Crop Breeding and Applied Biotechnology, 17:187-190.
Bustamante MA, Gomis MP, Pérez-Murcia MD, Gangi D, Ceglie FG, Paredes C, Pérez-Espinosa A, Bernal MP & Moral R (2021) Use of livestock waste composts as nursery growing media: Effect of a washing pre-treatment. Scientia Horticulturae, 281:109954.
Cavalcante LF, Sousa GG, Gondim SC, Figueiredo FL, Cavalcante ÍHL & Diniz AA (2009) Crescimento inicial do maracujazeiro amarelo manejado em dois substratos irrigados com água salina. Irriga, 14:504-517.
Cordeiro KV, Costa NA, Andrade HAF, Oliveira-Neto ED, Rocha BR, Farias MNA, Albano FG, Furtado MB & Silva-Matos RRS (2019) Inclusion of Babassu Decomposed Stem Growing medias on the Pattern of the Vegetative Growth of Passion Fruit Seedlings. Communications in Soil Science and Plant Analysis, 50:2777-2786.
Costa FM, Anjos GL, Camilo GBM, Oliveira UC, Souza GS & Santos AR (2018) Produção de mudas de maracujazeiro amarelo em diferentes composições de substrato e ambiente. Revista de Ciências Agrárias, 41:138-146.
Cruz CD (2013) Genes - a software package for analysis in experimental statistics and quantitative genetics. Acta Scientiarum, 35:271-276.
Dickson A, Leaf AL & Hosner JF (1960) Quality appraisal of white spruce and white pine seedling stock in nurseries. The Forestry Chronicle, 36:10-13.
Faria JCT, Lopes DA, Lyra GB, Melo HC & Melo LA (2019) Manejo da densidade de plantas durante a produção de mudas em viveiro. Ciência Florestal, 29:1187-1198.
Gavilanes-Terán I, Jara-Samaniego J, Idrovo-Novillo J, Bustamante M, Pérez-Murcia MD, Pérez-Espinosa A, López M & Paredes C (2017) Agroindustrial compost as a peat alternative in the horticultural industry of Ecuador. Journal of Environmental Management, 186:79-87.
Gibson EL, Gonçalves EDO, Ramalho A, Santos D, Araújo EF, Vinicius M & Caldeira W (2019) Controlled-Release Fertilizer on Growth of Melanoxylon brauna Schott Seedlings. Floresta e Ambiente, 26:01-07.
González-Orozco MM, Prieto-Ruíz JA, Aldrete A, Hernández-Díaz JC, Chávez-Simental JA & Rodríguez-Laguna R (2018) Nursery production of Pinus engelmannii Carr. with growing medias based on fresh sawdust. Forests, 9:01-15.
Ingram DL (2014) Understanding Soilless Media Test Results and Their Implications on Nursery and Greenhouse Crop Management. Agriculture and Natural Resources Publications, 161.
Junghans TG, Rosa RCC & Girardi EA (2017) Produção de mudas de maracujazeiro. In: Junghans TG & Jesus ON (Eds.) Maracujá: do cultivo à comercialização. Brasília, Embrapa Mandioca e Fruticultura. p.101-114.
Krause MR, Monaco PAVL, Haddade IR, Meneghelli LAM & Souza TD (2017) Aproveitamento de resíduos agrícolas na composição de substratos para produção de mudas de tomateiro. Horticultura Brasileira, 35:305-310.
Madrid-Aispuro RE, Prieto-Ruíz JA, Aldrete A, Hernández-Díaz JC, Wehenkel C, Chávez-Simental JA & Mexal JG (2020) Alternative growing medias and fertilization doses in the production of Pinus cembroides Zucc. in nursery. Forests, 11:01-13.
Mariotti B, Martini S, Raddi S, Tani A, Jacobs DF, Oliet JA & Maltoni A (2020) Coconut coir as a sustainable nursery growing media for seedling production of the ecologically diverse Quercus species. Forests, 11:04-07.
Massa D, Malorgio F, Lazzereschi S, Carmassi G, Prisa D & Burchi G (2018) Evaluation of two green composts for peat substitution in geranium (Pelargonium zonale L.) cultivation: Effect on plant growth, quality, nutrition, and photosynthesis. Scientia Horticulturae, 228:213-221.
Mendes RF, Araújo JC, Andrade Neto RCA, Araújo JM & Guilherme JPM (2019) Crescimento de mudas de maracujazeiro em substrato alternativo com fertilizante de liberação controlada. Revista Brasileira de Agropecuária Sustentável, 9:34-40.
Méndez A, Paz-Ferreiro J, Gil E & Gascó G (2015) The effect of paper sludge and biochar addition on brown peat and coir based growing media properties. Scientia Horticulturae, 193:225-230.
Mendonça A, Natale W, Sousa GG & Silva FB (2021) Morphophysiology and nutrition of yellow passion fruit seedlings grown in growing medias based on carnaúba palm bagana. Revista Brasileira de Ciências Agrárias, 16:01-07.
Monaco PAVL, Vieira JC, Colombo JN, Krause MR, Vieira GHS & Almeida KM (2020) Use of agricultural waste material as an alternative growing media in cabbage seedling production and development. Emirates Journal of Food and Agriculture, 32:131-139.
Mota CS, Silva FG, Dornelles P, Freiberger MB, Reis DN & Mendes GC (2018) Parameters of Physiology, Nutrition and Quality of Eugenia dysenterica DC Seedlings Grown in Organic Growing medias from the Agricultural Industry. Journal of Agricultural Science, 10:73-84.
Muniz PSB, Andrade Neto RC, Lunz AM, Almeida UO & Araújo JM (2020) Alternative substrates and controlled-release fertilizer in the production of yellow passion fruit seedlings. Comunicata scientiae, 10:01-10.
Neres YXC, Azevedo GTOS, Souza AM, Azevedo GB & Teodoro PE (2019) Effect of the hydrogel incorporation on different growing medias on the rooting and quality of clonal Eucalyptus seedlings. Scientia Forestalis, 47:336-345.
Nieto A, Gascó G, Paz-Ferreiro J, Fernández JM, Plaza C & Méndez A (2016) The effect of pruning waste and biochar addition on brown peat based growing media properties. Scientia Horticulturae, 199:142-148.
Noguera P, Abad M, Puchades R, Maquieira A & Noguera V (2003) Influence of particle size on physical and chemical properties of coconut coir dust as container medium. Communications in soil science and plant analysis, 34:593-605.
Oliveira JTD & Oliveira RAD (2021) Path analysis of physical attributes of chayote fruit. Engenharia Agrícola, 41:468-474.
Silva LN, Lima LKS, Santos IS, Sampaio SR & Jesus ON (2022) Multivariate strategies for selection of organic growing media to produce yellow passion fruit seedlings. Organic Agriculture, 12:445-459.
Silva NM, Souza SLG, Uchôa TL, Almeida WA, Araújo Neto SE & Ferreira RLF (2018) Qualidade de mudas orgânicas de maracujazeiro amarelo produzidas com substratos alternativos. Agropecuária Científica no Semiárido, 14:96-102.
Silva PCR, Paiva PEB, Charlo HCO & Coelho VPM (2020) Slow Release Fertilizers or Fertigation for Sugarcane and Passion Fruit Seedlings? Agronomic Performance and Costs. Journal of Soil Science and Plant Nutrition, 20:2175-2181.
Smiderle OJ, Souza ADG & Menegatti RD (2020) Controlled-Release Fertilizer in the Production of Seedlings of Anonna cacans Warm. Journal of Agricultural Studies, 8:125-133.
Streck EA, Aguiar GA, Magalhães Júnior AM, Facchinello PHK & Oliveira AC (2017) Variabilidade fenotípica de genótipos de arroz irrigado via análise multivariada. Revista Ciência Agronômica, 48:101-109.
Vejan P, Khadiran T, Abdullah R & Ahmad N (2021) Controlled release fertilizer: A review on developments, applications and potential in agriculture. Journal of Controlled Release, 339:321-334.
Wang P, Yang Y, Mou P, Zhao Q & Li Y (2018) Local root growth and death are mediated by contrasts in nutrient availability and root quantity between soil patches. Proceedings of the Royal Society B: Biological Sciences, 285:20180699.
Zorzeto TQ, Dechen SCF, Abreu MF & Fernandes Júnior F (2014) Caracterização física de substratos para plantas. Bragantia, 73:300-311.

Publication Dates

Publication in this collection
22 Apr 2024
Date of issue
2024

History

Received
13 Apr 2023
Accepted
23 July 2023

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] 1
This article is part of the Master Dissertation of the first author.

Growing medias	pH	EC¹ 1 EC: electrical conductivity;	N	P	K	Ca	Mg	S	OC² 2 OC: organic carbon;	C/N³ 3 C/N: carbon/nitrogen ratio;
Growing medias	pH	dS m^-1	–––––––––– g kg^-1 ––––––––––							-
Bcf+Ascb	5.1	0.4	9.9	0.9	7.9	2.4	1.5	1.2	334.4	34/1
Bcf+Laf	5.8	1.1	16.3	2	11.4	2.2	1.9	1.3	397.1	24/1
Bcf+Lcf	6.6	0.7	9.9	1.8	10.8	3.6	1.8	1.1	391.2	40/1
Bcf+Al	6.4	1.2	7.3	1	7.8	1.4	1.2	0.8	373.9	51/1
Bcf+Com	6.7	0.6	7.4	2.2	11	7.2	2.4	2.1	296.3	40/1
Ascb+Laf	5	0.3	17.3	1.3	4.4	4.3	1.6	1.4	304.7	18/1
Ascb+Lcf	5.4	0.1	11.2	1	4.6	3.6	1.2	1	281.2	25/1
Ascb+Al	4.9	0.5	10.7	0.5	3.4	2.3	1	0.8	323.3	30/1
Ascb+Com	4.5	0.6	7.2	1.5	3.1	6.5	2	1.9	218.6	30/1
Laf+Lcf	6.2	0.7	20.1	3.1	10.1	4.2	2	1.5	339.7	31/1
Laf+Al	4.8	1.2	13.8	1.7	6.3	1.8	1.3	1.1	388.9	28/1
Laf+Com	6.7	0.6	16	3.6	7.7	13.2	3.5	3.1	334.1	21/1
Lcf+Al	4.2	1.1	10.8	1.7	7.5	3.1	1.6	1.2	330.2	17/1
Lcf+Com	5.9	0.6	10	2.8	7.6	10.9	2.7	2.9	318.4	32/1
Al+Com	4.8	1.3	9.5	2.2	7	6.6	2.2	2.1	289.4	31/1
Bcf^a	7.5	1.1	6.6	2.1	1.4	11.9	4.3	0.9	432.9	65/1
Ascb^b	4.6	0.1	10.6	0.9	1.8	15.9	2.3	0.8	300.2	28/1
Laf^b	6.5	0.5	22.1	1.7	9.1	12.8	1.8	0.9	374.3	17/1
Lcf	6.7	0.4	9.3	0.9	14.1	3.4	1.6	1	390.3	42/1
Al	5.7	1.2	8.2	2.4	7.3	13.6	2.3	1.6	401.6	49/1
Com^b	5.6	1.1	3.3	2.1	2.7	8.8	1.9	2.1	154.3	47/1
Growing medias	Fe	B	Cu	Mn	Zn	Hy⁴ 4 Hy: humidity;	Wd⁵ 5 Wd: wet density;	Dd⁶ 6 Dd: dry density;	WRC⁷ 7 WRC: water retention capacity;	CEC⁸ 8 CEC: cation exchange capability.
Growing medias	––––––––––mg kg^-1 ––––––––––					%	––––– kg m^-3 –––––		%v/v	mmol_c dm^-3
Bcf+Ascb	1900	11.5	13	108.1	28.2	8	415.1	381.9	57.4	232.3
Bcf+Laf	900	15	12.3	54.2	38.5	6	398.7	374.6	55.2	163.9
Bcf+Lcf	800	12.6	10.7	52.4	28.4	3.8	394.5	379.8	61.7	182
Bcf+Al	400	10.5	9	144	20.2	4.2	614.4	588.6	59.2	185.1
Bcf+Com	2400	10.6	10	86.9	25.9	16.3	315.8	264.5	43.6	162.9
Ascb+Laf	1600	12.8	15.2	107.1	31	8.8	326.3	297.5	48.2	225.2
Ascb+Lcf	1700	10.6	14.6	112.3	24.6	15.5	319.5	270.1	31.4	228.6
Ascb+Al	1100	7.9	10.2	144.7	21.2	9.8	516.3	465.7	47.7	269.1
Ascb+Com	3600	8.5	10.2	134.6	23.4	22.8	554.5	427.9	48.8	277.2
Laf+Lcf	400	17.5	13.5	47.3	37.6	11.7	262.1	231.3	62.8	141.1
Laf+Al	800	12.4	11.4	194.6	31	8.1	469.2	431.2	48.4	235.6
Laf+Com	3800	14.3	13.1	127.6	30.3	40.2	286.8	171.5	37.9	180.1
Lcf+Al	600	11	12.9	277.6	21.8	15.8	444.8	374.6	37.4	241.6
Lcf+Com	2900	11.9	11.1	84.6	21.1	29.9	238.2	167.1	34.8	123.2
Al+Com	3100	9.4	12.5	278.1	32.9	17.9	383.3	314.7	47.6	201.4
Bcf	6200	23.4	35.3	199.1	72.1	5.8	488.6	460.5	83.5	166.1
Ascb	11400	27.6	23.3	267	38.6	52	573.1	275	75.3	382.1
Laf	1600	10.7	10.6	40	18.9	9.2	265.8	241.5	73.6	129.1
Lcf	1100	5.8	8.3	46.3	21.2	11.3	232.1	205.8	81.9	105.9
Al	1300	14.1	20.9	68.9	56.8	12.8	568.1	495.5	66.3	93
Com	4500	7.7	6.7	84.5	15.7	25.2	508.9	380.8	44.4	319.3

Sources of variation	g.l	Mean Square
Sources of variation	g.l	H	SD	HSD	NL
Growing media (G)	20	204645.65^* * = significant effect by the F test at 5% of probability;	4.77^* * = significant effect by the F test at 5% of probability;	10865.44^* * = significant effect by the F test at 5% of probability;	44.03^* * = significant effect by the F test at 5% of probability;
Fertilization (F)	1	28961747.43^* * = significant effect by the F test at 5% of probability;	580.36^* * = significant effect by the F test at 5% of probability;	1707290.31^* * = significant effect by the F test at 5% of probability;	6403.20^* * = significant effect by the F test at 5% of probability;
G x F	20	212463.89^* * = significant effect by the F test at 5% of probability;	4.97^* * = significant effect by the F test at 5% of probability;	11736.82^* * = significant effect by the F test at 5% of probability;	50.43^* * = significant effect by the F test at 5% of probability;
Block	2	96028.22^* * = significant effect by the F test at 5% of probability;	0.28^ns ns = not significant effect according to the F test at 5%.	10055.04^* * = significant effect by the F test at 5% of probability;	12.25^* * = significant effect by the F test at 5% of probability;
Residual	687	5702.30	0.11	498.64	1.66
C.V (%)	-	29.24	13.73	25.12	17.39
Mean	-	28.24	2.37	8.91	7.41
Sources of variation	g.l	SDM	RDM	TDM	DQI
Growing media (G)	20	6.88^* * = significant effect by the F test at 5% of probability;	0.37^* * = significant effect by the F test at 5% of probability;	1.57^* * = significant effect by the F test at 5% of probability;	0.033560^* * = significant effect by the F test at 5% of probability;
Fertilization (F)	1	1352.15^* * = significant effect by the F test at 5% of probability;	37.73^* * = significant effect by the F test at 5% of probability;	350.67^* * = significant effect by the F test at 5% of probability;	3.446883^* * = significant effect by the F test at 5% of probability;
G x F	20	6.57^* * = significant effect by the F test at 5% of probability;	0.37^* * = significant effect by the F test at 5% of probability;	1.73^* * = significant effect by the F test at 5% of probability;	0.037312^* * = significant effect by the F test at 5% of probability;
Block	2	1.17^* * = significant effect by the F test at 5% of probability;	0.007^ns ns = not significant effect according to the F test at 5%.	0.21^* * = significant effect by the F test at 5% of probability;	0.003633^ns ns = not significant effect according to the F test at 5%.
Residual	687	0.16	0.008	0.02	0.000969
C.V (%)	-	25.57	28.98	10.94	27.91
Mean	-	1.57	0.32	1.12	0.111

Brasil