EFFECT OF CHARCOAL -ENRICHED SUBSTRATE ON SEEDLINGS OF RHIZOBIUM-INOCULATED LEGUME TREES

Freitas, Aroldo Felipe de; Souza, Luiz Augusto Gomes de; Cardoso, Irene Maria; Venturin, Nelson

doi:10.1590/0100-67622016000600010

ABSTRACT

Native legume trees are planted in agroforestry systems for their hardiness and symbiosis with soil bacteria of the genus rhizobium, efficient in N2 fixation. The enrichment of the substrate composition with fine charcoal for seedling production of these trees is interesting for increasing soil porosity, water retention and the proliferation of beneficial microorganisms. Experiments were carried out to analyze the effect of substrate enrichment with charcoal on the quality of Clitoria fairchildiana, Enterolobium schomburgkii and Inga edulis seedlings. The treatments consisted of a 3:2:0.5 (v:v) mixture of clay soil, sand and bovine manure and a 3:2 (v:v) mixture of clay soil and sand combined with charcoal rates of 0, 10, 19 and 29%. After mixing the components, substrate samples were collected and chemically analyzed. The experiment was arranged in a completely randomized design with 5 treatments and 10 replications. The seedlings were inoculated with homologues rhizobia and growth controlled monthly. The plants were collected to determine the number of nodules and dry biomass of roots, shoots and nodules. Seedling growth was similar on substrates containing charcoal or manure, except for E. schomburkii, which increased by more than 100% on the charcoal-containing substrates. The number and dry biomass of nodules in the charcoal-containing substrates was up to 100% and 300% higher than in the manure-containing treatment, respectively. The results indicated that the substitution of manure by charcoal favors the seedling quality of the studied species.

Keywords:
Inga edulis; Enterolobium schomburgkii; Clitoria fairchildiana

RESUMO

O estabelecimento do plantio florestal com mudas bem noduladas favorece o seu crescimento inicial e sobrevivência após a fase de estabelecimento. As espécies leguminosas arbóreas ingá (Inga edulis), orelha-de-macaco (Enterolobium schomburgkii) e palheteira (Clitoria fairchildiana) têm sido recomendadas para recuperação de áreas degradadas e composição de sistemas agroflorestais pela sua rusticidade e capacidade de estabelecer simbiose com bactérias do solo do grupo dos rizóbios, eficientes em fixar N². Foi conduzido estudo experimental para analisar o efeito da adição de carvão vegetal em mistura substrato sobre a qualidade de mudas produzidas em viveiro. Os tratamentos utilizados foram: mistura 3:2:0,5 (v:v) de solo argiloso, areia e esterco bovino e de solo argiloso e areia 3:2 (v:v), combinado com carvão vegetal em dosagem de 0, 10, 19 e 29 % de carvão em mistura. Amostras das misturas substratos foram coletadas e analisadas quimicamente. O delineamento foi o inteiramente casualizado com cinco tratamentos e dez repetições. As mudas foram inoculadas com estirpes homólogas de rizóbios, sendo que 5 mL planta-1 foram aplicados na base do coleto das mudas. O crescimento das mudas foi acompanhado mensalmente e as plantas foram coletadas para contagem do número de nódulos formados e determinação da biomassa das raízes, parte aérea e nódulos após secagem a 65ºC/72 h. O uso de esterco na composição dos substratos inibiu a nodulação em todas as três espécies estudadas. Foi também possível verificar aumento na qualidade das mudas pelo uso de carvão no substrato.

Palavras-chave:
Inga edulis; Enterolobium schomburgkii; Clitoria fairchildiana

1. INTRODUCTION

The production of high-quality seedlings is a prerequisite for the success of forest enterprises (CUNHA et al., 2006CUNHA, A.O.; ANDRADE, L.A.; BRUNO, R.L.A.; SILVA, J.A.L.;SOUZA, V.C. Efeitos de substratos e das dimensões dos recipientes na qualidade das mudas de Tabebuia impertiginosa (Mart. Ex D.C.) Standl. Revista Árvore, v.29, n.4, p.507-516, 2006.). Biometric characteristics and other indicators can be used in the final phase of seedling production to evaluate the quality and moment when the plantlets are ready for the final planting, eliminating those without vigor (FONSECA et al., 2002FONSECA, E.P.; VALERI, S.V.; MIGLIORANZA, E.; FONSECA, N.A.N.; COUTO, L. Padrão de qualidade de mudas de Trema micrantha (L.) Blume, produzidas sob diferentes períodos de sombreamento. Revista Árvore, v.26, n.4, p.515-523, 2002.). Among the most commonly used indicators of seedling quality are biomass, stem length or diameter, stem flexibility, and height/diameter and shoot/root ratios, Dickson Quality Index and leaf area (GOMES; PAIVA, 2006GOMES, J.M.; PAIVA, H.N. Viveiros florestais. Viçosa, MG: Universidade Federal de Viçosa, 2006. 116p.).

A goal of forestry research is the establishment of quality indicators for the most important species. To this end, the Dickson Quality Index (DQI) (DICKSON et al., 1960DICKSON, A.; LEAF, A.; HOSNER, J.F. Quality appraisal of white spruce and white pine seedling stock in nurseries. Forestry Chronicle, v.36, p.10-13, 1960.) serves as a supports for a more holistic interpretation of the research results of seedling production, by condensing various quality indicators in a single index of easy interpretation. The higher the value of this index, the higher is the seedling quality (FONSECA et al., 2002FONSECA, E.P.; VALERI, S.V.; MIGLIORANZA, E.; FONSECA, N.A.N.; COUTO, L. Padrão de qualidade de mudas de Trema micrantha (L.) Blume, produzidas sob diferentes períodos de sombreamento. Revista Árvore, v.26, n.4, p.515-523, 2002.). However, this index must be calculated specifically for each species of interest.

Ice-cream-bean (Inga edulis), orelha-de-macaco (Enterolobium schomburgkii) and palheteira (Clitoria fairchildiana) are promising legume tree species for agroforestry, in view of their capacity to fix atmospheric N in a symbiotic relationship with bacteria and of their rapid growth, even under adverse conditions. Palheteira has been used for urban afforestation and recovery of degraded areas due to its leafy canopy and beautiful flowers. Orelha-de-macaco is also interesting because of its high-density wood, with good mechanical strength and moderate durability. Orelha-de-macaco is indicated as veneer wood, for the construction of car bodies, timber flooring, and for external constructions. Ice-cream-bean wood is used for boxes, firewood and charcoal and the flavor of its fruits is highly appreciated by the populations of the Amazon region, where it is grown in backyards and sold on open markets (LORENZI, 2002LORENZI, H. Árvores brasileiras. Nova Odessa: Instituto Plantarum, 2002. 381p.).

To grow high-quality seedlings of these species, the required inputs must be readily available and cheap (BERNARDINO et al., 2005BERNARDINO, D.C.S.; PAIVA, H.N.; NEVES, J.C.L.; GOMES, J.M.; MARQUES, V.B. Crescimento e qualidade de mudas de Anadenanthera macrocarpa (Benth.) Brenan em resposta à saturação por bases do substrato. Revista Árvore, v.29, n.6, p.863-870, 2005.; CUNHA et al., 2006CUNHA, A.O.; ANDRADE, L.A.; BRUNO, R.L.A.; SILVA, J.A.L.;SOUZA, V.C. Efeitos de substratos e das dimensões dos recipientes na qualidade das mudas de Tabebuia impertiginosa (Mart. Ex D.C.) Standl. Revista Árvore, v.29, n.4, p.507-516, 2006.), if possible based on recyclable by-products such as charcoal residues. The use of charcoal powder can contribute to the economic viability of seedling production, for being a cheap by-product, a residue of the selection of larger charcoal for the market.

Charcoal is present in the anthropogenic eutrophic soil classified as Terra Preta de Índio, contributing to the improvement of the soil physical properties by the formation of organic matter more resistant to microbial digestion. Consequently, charcoal is one of the factors that maintains the fertility of this soil class after consecutive crops (GLASER et al., 2001GLASER, B.; HAUMAIER, L.; GUGGENBERGER, G.; ZECH, W. The Terra Preta phenomenon - a model for sustainable agriculture in the humid tropics. Naturwissenschaften, v.88, n.1, p.37-41, 2001.; MAJOR et al., 2005MAJOR,J.; DITOMMASO, A.; LEHMANN, J.; FALCÃO, N.P.S. Weed dynamics on Amazonian Dark Earth and adjacent soils of Brazil. Agriculture, Ecosystems and Environment, v.11, p.1-12, 2005.; MOREIRA, 2007MOREIRA, A. Fertilidade, matéria orgânica e substâncias húmicas em solos antropogênicos da Amazônia Ocidental. Bragantia, v.66, p.307-315, 2007.). The effect of the addition of fine wood charcoal to the soil, also known as "charcoal powder", has been studied recently in Brazil for improving soil properties, especially for increasing the proliferation of beneficial microorganisms, as those with capacity to fix atmospheric N in symbiosis with legumes (ZANETTI et al., 2003ZANETTI, M.; CAZETTA, J.O.; MATTOS JUNIOR, D.; CARVALHO, S.A. Uso de subprodutos de carvão vegetal na formação de porta-enxerto limoeiro 'cravo' em ambiente protegido. Revista Brasileira de Fruticultura, v.25, n.3, p.508-512, 2003.; RONDON et al., 2007RONDON, M.A., LEHMANN, J.; RAMÍREZ, J.; HURTADO, M. Biological nitrogen fixation by common beans (Phaseolus vulgaris L.) increases with bio-char additions. Biology Fertility Soils, v.43, p.699-708, 2007.; STEINER et al., 2008).

The use of wood charcoal in the development of forest seedlings has not yet been investigated, especially for legume trees. This research was developed to evaluate the effect of the enrichment of substrate mixtures with fine charcoal at different rates on the growth, nodulation and efficiency of symbiotic N₂ fixation of seedlings of Clitoria fairchildiana, Enterolobium schomburgkii and Inga edulis.

2. METHODOLOGY

2.1 Description of the experiment

The experiments were conducted in 2011 and 2012 on the Campus INPA V-8 in areas of seedbeds and greenhouses of the Coordination of Society, Environment and Health of the National Research Institute of the Amazon (CSAS-INPA), in Manaus, Amazonas (AM), Brazil. According to Köppen, the climate of Manaus is classified as Afi - tropical rainy, with annual means of 2,325 mm rainfall, temperature 26.6 ºC and relative humidity between 84 and 90% (INPE, 2003INSTITUTO NACIONAL DE PESQUISAS ESPACIAIS - INPE. [acessado em: jan. 28, 2013]. Disponível em: http://www.Cptec.inpe.br/clima/monit/monitor_brasil.shtml
http://www.Cptec.inpe.br/clima/monit/mon... ).

The area of seed beds consisted of wooden benches arranged in a laterally open shed covered with clay tiles. The structure of this greenhouse consisted of iron and was covered with shade net, with 50% light incidence, open sides, a cemented floor, an area of 8 x 11 m, and irrigation was applied through plastic hoses.

Seeds of ice-cream-bean (Inga edulis Mart, Mimosoideae) and palheteira (Clitoria fairchildiana R.A. Howard, Faboideae) were harvested from mother trees at the Experimental Station of Tropical Forestry of INPA (BR 174, km 46, Manaus, AM, Brazil). Seeds of orelha-de-macaco (Enterolobium schomburgkii Benth, Mimosoideae) were collected in Codajás, AM. Each species was evaluated in an experiment.

The fruits of ice-cream-bean were harvested directly from the tree canopy with a curved knife on an extra-long rod. The fruits of palheteira and orelha-de-macaco were collected under the canopy of the matrices in the peak phase of seed dispersal by barochory. After air-drying for 48 h, the fruits were processed to obtain pure seed at the INPA Soil Microbiology Laboratory.

Prior to sowing, the seeds of the three species were soaked in water for 24 h to promote imbibition. The orelha-de-macaco seeds underwent a pre-germination treatment consisting of cutting the tegument with tweezers on the far end of the embryo, while ice-cream-bean and palheteira seeds were not subjected to any pre-germination treatment apart from imbibition. One hundred and fifty ice-cream-bean and orelha-de-macaco seeds were sown in rows, using drained plastic boxes (40 x 80 x 15 cm) filled with washed sand. The seedlings were watered daily in the germination phase. When most of the seeds had germinated and grown a definite pair of leaves, 100 seedlings of similar size per species were transplanted to the substrates. For palheteira, three seeds per unit were sown directly in the bags already filled with the substrate mixtures, followed by thinning, sparing the most vigorous and most central plantlets.

The components of the substrate mixtures were clay soil, bovine manure, sand, and fine charcoal. The clay soil and the tanned bovine manure were collected on an experimental farm of the Federal University of Amazonas (UFAM), BR 174, Km 35, Manaus, AM. Yellow Latosol/Latossolo Amarelo soil was sampled to a depth of 10 cm in an area of abandoned pasture to ensure a higher quantity of native rhizobium inoculum (VIEIRA et al., 2011VIEIRA, E.P.; SOUZA, L.A.G. Inoculação com rizóbios em mudas de acapu do igapó e saboarana. Revista de Ciências Agrárias, v.54, n. 1, p.54-62, 2011.). Sand, classified as construction material, was purchased in Manaus. Fine charcoal, a byproduct of tree burning, was purchased from an authorized rural producer, licensed by the environmental agency, at BR 174, Ramal ZF-1, in the Community Nova Canaã, municipality of Manaus. This fine charcoal was composed of a mixture of wood of several species during charcoal production. This type of material is available on the market and was therefore used in the experiment, since this study was intended to represent the conditions for producers as close to reality as possible.

Each component was dried in the shade for 48 h and then sieved (5 mm mesh). The mixtures were prepared on a volumetric basis. The 3:2:0.5 (v:v) substrate mixture of clay soil, sand and bovine manure proposed for noduliferous legume trees (SOUZA, 2007SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007.) was chosen as control treatment. This allowed a comparison of the results with the quality of a scientifically proven substrate. The proportion of charcoal used in the treatments was estimated to meet the recommended application of 0, 40, 80, and 120 t ha^-1 of charcoal tested under field conditions by OLIVEIRA et al. (2010)OLIVEIRA, D.M.; FALCÃO, N.P.S.; SOUZA, L.A.G. Efeito do resíduo de carvão vegetal e pó de serra no crescimento vegetativo e na nodulação do feijão caupi (Vigna Unguiculata L. Walp) em Latossolo Amarelo distrófico da Amazônia Central. In: REUNIÃO CIENTÍFICA DA REDE CTPETRO AMAZÔNIA, 3., 2010, Manaus. Anais... Manaus: Instituto Nacional de Pesquisas da Amazônia, 2010. p.1-11.. The applied treatments were described in Table 1.

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Table 1
Proportions of substrate mixtures used for the production of leguminous seedlings.
Tabela 1
Proporções das misturas substrato utilizadas na formação de mudas leguminosas arbóreas.

2.2 Seedling cultivation

Samples of the isolated components and substrate mixtures were collected for laboratory analysis prior to sowing. After homogenization, the substrates were distributed in polypropene plastic bags (13 x 27 cm), properly drained, with a diameter of 11 cm after filling and volume of 2 kg. The seedlings were transplanted by the technique of naked roots after growing one pair of definitive leaves, in the case of ice-cream-bean and orelha-de-macaco. During the experiment, the substrates were irrigated regularly on days without rain and when necessary weeds were removed by hand.

The height and diameter of the root collar of ice-cream-bean and orelha-de-macaco seedlings were first measured one day after transplanting. The plant height was defined as the distance between the root collar and apical meristem of the plantlet. For palheteira, which was sown directly in the bags, growth measurement and thinning were first carried out after 19 days. From then on, the seedlings were measured monthly until harvest.

The seedlings were inoculated with strains of homologous rhizobia, preserved in the rhizobium collection of the Laboratory of Soil Microbiology of INPA. For this purpose, liquid YM inoculant (HUNGRIA et al., 1994HUNGRIA, M. Coleta de nódulos e isolamento de rizóbios. In: HUNGRIA, M.; ARAÚJO, R.S. (Ed.) Manual de métodos empregados em estudos de microbiologia agrícola. Brasília: Empresa Brasileira de Pesquisa Agropecuária, 1994. p.45-59.), pH 6.0, without dye, was distributed in 125 mL Erlenmeyer flasks and incubated for eight days on a mechanical stirrer. When no selected strains for local soils were available, the strains were combined in a cocktail, as follows: for ice-cream-bean, strains SMS 828, SMS 832, SMS 841, SMS 842, SMS 847, and SMS 850, for orelha-de-macaco, strains SMS 600, SMS 602, and SMS 617, and for palheteira, strains SMS 938, SMS 941, SMS 943, SMS 944, SMS 945, SMS 949, SMS 950, and SMS 959. The seedlings were treated with 5 mL of liquid inoculant applied at the stem base, 21 and 32 days after transplanting of ice-cream bean and orelha-de-macaco, and 27 days after germination of palheteira.

2.3 Harvesting of seedlings and laboratory analysis

The seedlings were harvested when the quality was sufficient for the final planting, i.e., 92 and 75 days after transplanting for ice-cream-bean and orelha-de-macaco, respectively, and 90 days after sowing for palheteira. On this occasion, the height and diameter of the root collar of the seedlings were measured and the whole plants were extracted after crumbling the substrate. Then they were washed and cut in shoots and roots. The nodules were detached from the roots, counted and separated. All of the plant material was oven-dried at 65ºC for 72 h, and weighed. For the shoots, the stem biomass was also determined and the leaf biomass calculated by subtraction.

The dried leaf material was ground in a knife mill and prepared to determine the N tissue concentration by acid digestion of the samples with sulfuric acid, by the modified Kjeldahl method. From the leaf N concentration, the total N content of the leaves was calculated.

The leaf N content and chemical properties of the isolated components and substrate mixtures were determined at the Thematic Laboratory of Soils and Plants - LTSP/INPA, in Manaus, AM. The pH of the substrates in water (1:2.5) and Ca, Mg and Al contents were determined in 1N KCl extraction solution (EMBRAPA, 1997EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Manual de métodos de análise de solo. Rio de Janeiro: Centro Nacional de Pesquisa de Solos, 1997. 212p.). The C content was determined by the Walkley-Black method (MENDONÇA; SILVA, 2001MENDONÇA, E.S.; MATOS, E.S. Matéria orgânica do solo: Método de análises. Viçosa, MG: Universidade Federal de Viçosa, 2005.107p.) and the organic matter content estimated from the C content (C content x 1.72). Potassium was determined by flame photometry, P extracted and determined by spectrophotometry, and Zn and Fe were extracted in Mehlich-1 solution and quantified in atomic-absorption readings.

The dried leaf material was ground in a knife mill and prepared to determine N concentration in the tissue. To this end, the samples were acid-digested with sulfuric acid by the modified Kjehdal method. The leaf N values were multiplied by the shoot dry weight to calculate cumulative N in the shoot.

2.4 Data analysis and experimental design

From the above results, the ratio of Shoot Dry Weight/Root Dry Weight (SDW/RDW) was calculated. The Dickson Quality Index (DQI) (DICKSON et al., 1960DICKSON, A.; LEAF, A.; HOSNER, J.F. Quality appraisal of white spruce and white pine seedling stock in nurseries. Forestry Chronicle, v.36, p.10-13, 1960.) was also determined by the formula:

DQI = \frac{T D W (g)}{[H (c m) / D (m m)] + [S D W (g) / R D W (g)]}

where TDW is the total dry matter, H the plant height, D the root collar diameter, SDW the shoot dry weight, and RDW the root dry weight.

For all tree species, the experimental design was completely randomized, with 5 treatments and 10 replications for measurements of growth and biomass and 5 replications for analyses of leaf N contents. For the analysis, the number and dry biomass of the nodules were transformed with √_(x+0.01), and the leaf N content and cumulative shoot N content with arc sine √_(x+0.01), as recommended by Centeno (1990)CENTENO, A.J. Curso de estatística aplicada à biologia. Goiânia: UFG, 1990. 188p.. The results were analyzed using software Estat, developed by UNESP, version 2002 and the means compared by Tukey's test at a probability of 5%.

3. RESULTS

Important differences were observed between the chemical characteristics of the components and the substrate mixtures (Table 2). The pH of charcoal was the lowest, followed by the pH of clay soil, manure and sand.

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Table 2
Chemical characteristics of the separate components and substrate mixtures used for the production of leguminous seedlings.
Tabela 2
Características químicas dos componentes isolados e das misturas substrato empregadas na formação de mudas leguminosas arbóreas.

The tested substrates did not affect the growth parameters, SDW/RDW ratio, and DQI of ice-cream bean and palheteira, but had a significant influence (P <0.05) on the development of orelha-de-macaco seedlings (Table 3). Ice-cream bean and palheteira needed a period of about 90 days in the greenhouse to reach a plant height of 30 cm, whereas 175 days after thinning, orelha-de-macaco had not reached a height of 20 cm in most of the substrates.

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Table 3
Effect of substrate on quality parameters of legume tree seedlings.⁽¹ (1) Means followed by the same letter in columns do not differ by the Tukey test at a probability of 5% (P<0.05), ns = not significant, Inga edulis, Enterolobium shomburkii and Clitoria fairchildiana were harvested, respectively, 92 and 175 days after thinning and Clitoria fairchildiana 90 days after sowing. ⁾
Tabela 3
Efeito do substrato sobre parâmetros de avaliação da qualidade de mudas de leguminosas arbóreas.⁽¹ (1) Means followed by the same letter in columns do not differ by the Tukey test at a probability of 5% (P<0.05), ns = not significant, Inga edulis, Enterolobium shomburkii and Clitoria fairchildiana were harvested, respectively, 92 and 175 days after thinning and Clitoria fairchildiana 90 days after sowing. ⁾

The experimental data indicated the worst performance of orelha-de-macaco seedlings when grown in the 3:2:0.5 mixture of clay soil, sand and cattle manure (S_e) (Table 3). On the substrates with charcoal and on the 3:2 clay soil and sand mixture (S), orelha-de-macaco plants had significantly taller heights and a greater biomass of dry roots (P <0.05) than those grown in S_e. The increase in root collar diameter of orelha-de-macaco seedlings was also significantly affected in response to the substrate mixtures. In this case, the largest root collar diameter was verified in the mixture S, significantly larger than measured in the mixture of 1.5:2:1 clay soil, sand and charcoal (S_3c) and S_e.

The measures of shoot and root growth of orelha-de-macaco were also significantly affected by the substrate used. For root growth, as mentioned above, the mixture S_e was not beneficial for the species. For shoot biomass, the plants grown in mixture S were significantly superior to those grown in S_e and in the 5.5:3.5:1 mixture of clay soil, sand and charcoal (S_1c).

The lowest and most balanced SDW/RDW ratio of orelha-de-macaco plants was 1.48 in the substrate mixture S_1c, where the shoot diameter and dry matter were also highest. For the DQI of orelha-de-macaco seedlings, was around 0.30 in all treatments with charcoal, being more than three times higher and statistically different from S_e with a DQI of 0.08.

For being nodular legume and N₂-fixing trees, the effect of charcoal in the substrate mixture is not only reflected in plant growth data, but also expressed in the nodulation characteristics and N uptake by the seedlings. In this sense, the experimental results indicated a significant effect of the substrates on nodulation characteristics of the three studied legume tree species (Table 4). On the other hand, considering the N uptake by the leaf N contents and shoot N accumulation, only ice-cream-bean was irresponsive to the different substrate mixtures, absorbing N efficiently in all tested combinations.

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Table 4
Effect of substrate on nodulation and nitrogen content of legume tree seedlings.⁽¹ (1) Means followed by the same letter in columns do not differ by the Tukey test at a probability of 5% (P<0.05), ns = not significant, Inga edulis, Enterolobium schomburkii were harvested, respectively, 92 and 175 days after thinning and Clitoria fairchildiana 90 days after sowing. ⁾
Tabela 4
Efeito do substrato sobre a nodulação e teor de nitrogênio de mudas leguminosas arbóreas.⁽¹ (1) Means followed by the same letter in columns do not differ by the Tukey test at a probability of 5% (P<0.05), ns = not significant, Inga edulis, Enterolobium schomburkii were harvested, respectively, 92 and 175 days after thinning and Clitoria fairchildiana 90 days after sowing. ⁾

The development of ice-cream bean seedlings in S_e in comparison with the charcoal-containing substrates was not favorable for nodule formation, which was evaluated by the nodule number (NN) and nodule dry weight (NDW) (Table 4). Thus, in S and all mixtures with charcoal, the NN of ice-cream-bean was significantly higher (P <0.05) than in S_e. On the other hand, for the seedlings grown in S_1c and S_2c, NDW was also significantly higher than that of seedlings developed in S_e. Without significant differences, the mean leaf N content and shoot N accumulation of ice-cream-bean seedlings was 34.7 g kg^-1 and 91.3 mg plant^-1, respectively.

The species orelha-de-macaco was more sensitive than ice-cream-bean to charcoal addition and formed no nodules in the substrate with manure, under the experimental conditions (Table 4). The NN on orelha-de-macaco roots was higher in S than in the mixture with the lowest charcoal rate, S_1c. The evaluation of NDW in orelha-de-macaco showed that the nodular growth of seedlings grown in S, S_2c and S_3c was significantly higher than in S_1c.

In general, in comparison with orelha-de-macaco, the rapid growth and high N accumulation in the biomass of ice-cream-bean and palheteira plants, regardless of the substrate tested, indicated great robustness. This hardiness of ice-cream-bean and palheteira in response to the substrates with lower nutrient availability may be explained by an investment of the plants in nodulation, maintaining the N content unchanged.

4. DISCUSSION

Charcoal and bovine manure contain more nutrients than sand and clay soil. However, there are important differences between charcoal and manure, which can lead to different results in seedling production. In the case studied, the organic matter (OM) content of charcoal was 3.5 times higher than that of manure, while the Ca and Mg contents were similar as in manure. Under the tested conditions, the P, K, Fe and Zn contents in manure were far higher than in charcoal, particularly with regard to the available P content. The results confirmed that the key contribution of charcoal to an improved substrate quality are not the chemical characteristics, but the potential to enhance the physical parameters of the substrate by raising the OM content and by improving porosity and water retention of the substrate (TRYON, 1948TRYON, E.H. Effect of charcoal on certain physical, chemical, and biological properties of forest soils. Ecological Monographs, v.18, n.1, p.81-115, 1948.; ZANETTI et al., 2003ZANETTI, M.; CAZETTA, J.O.; MATTOS JUNIOR, D.; CARVALHO, S.A. Uso de subprodutos de carvão vegetal na formação de porta-enxerto limoeiro 'cravo' em ambiente protegido. Revista Brasileira de Fruticultura, v.25, n.3, p.508-512, 2003.). However, the physical quality of the substrates was not analyzed in this study.

The chemical analysis of the substrate clearly showed that charcoal addition reduced the availability of most nutrients and of OM, and that the pH became more acidic than in S_e (Table 2). Moreover, the P contents in S_e (110.1 mg kg^-1) were in the mean 10 times higher than the P content in the substrates with charcoal, where the availability of this element was highest in S_3c (15.6 mg kg^-1). In this substrate with highest charcoal content, the contents of OM, Ca, Mg, and Fe were similar to those of S_e, while the K content was higher than in S_e, indicating that charcoal provides high amounts of this essential element. In addition, S_3c stood out among the substrates with charcoal and in comparison with S with higher contents of OM, Mg, P, K, Zn, and Mn. The improvements in the chemical properties of the substrates due to the effect of charcoal addition observed in this study were inferior to those described by Tryon (1948)TRYON, E.H. Effect of charcoal on certain physical, chemical, and biological properties of forest soils. Ecological Monographs, v.18, n.1, p.81-115, 1948. and Chidumayo (1994)CHIDUMAYO, E.N. Effects of wood carbonization on soil and initial development of seedlings in miombo woodland, Zambia. Forest Ecology and Management, v.70, n.1, p.353-357, 1994., who reported that the pH was neutralized by increasing the charcoal rates (Table 2). Therefore, when adding charcoal to substrates, the variation in pH and nutrient contents according to the species or species mixture used for wood carbonization should be taken into account (SANTOS et al., 2013SANTOS, R.C.; CARNEIRO, A.C.O.; PIMENTA, A.S.; CASTRO, R.V.O.; MARINHO, I.V.; TRUGILHO, P.F.; ALVES, I.C.N.; CASTRO, A.F.N.M. Potencial energético da madeira de espécies oriundas de plano de manejo florestal no estado do Rio Grande do Norte. Ciência Florestal, v.23, n.2, p.491-502, 2013)

The results in seedling quality were also lower than expected, since Souchie et al. (2011)SOUCHIE, F.F.; MARIMON JUNIOR, B.H.; PETTER, F.A.; MADARI, B.E.; MARIMON, B.S.; LENZA, E. Carvão pirogênico como condicionante para substrato de mudas de Tachigali vulgaris L.G.Silva & H.C.Lima. Ciência Florestal, v.21, n.4, p. 811-821, 2011. observed improvements directly proportional to the increase of charcoal in the substrate of Tachigali vulgaris, while in this experiment the improvement in the seedling quality did not accompany the increase of charcoal in the substrate.

The larger seed size may have been responsible for the lower plasticity of response to the substrates of ice-cream-bean and palheteira compared to orelha-de-macaco plants (Table 3), by providing greater independence due to the accumulated reserves in a larger seed (UCHIDA; CAMPOS, 2000UCHIDA, T.; CAMPOS, M.A.A. Influência do sombreamento no crescimento de mudas de cumaru (Dipteryx odorata (Aubl.) Willd. - Fabaceae), cultivadas em viveiro. Acta Amazônica, v.30, n.1, p.107-114, 2000.).

At the time of harvest, the seedlings of the species under study had a taller mean height (Table 3) than the minimum height of 15 to 30 cm, recommended by Gomes and Paiva (2006)GOMES, J.M.; PAIVA, H.N. Viveiros florestais. Viçosa, MG: Universidade Federal de Viçosa, 2006. 116p., except for the orelha-de-macaco plants in S_e. Palheteira plants had a taller mean height than the 20.4 cm reported for this spescies in a study of Portela et al. (2001)PORTELA, R.C.Q.; SILVA, I.L.; PINÃ-RODRIGUES, F.C.M. Crescimento inicial de mudas de Clitoria fairchildiana Howard e Peltophorum dubium (Sprenge) Taub em diferentes condições de sombreamento. Ciência Florestal, v.11, n.2, p.163-170, 2001., 150 days after sowing on substrate with 50% soil and 50% urban waste compost. On the other hand, in a study of Souza et al. (2007)SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007., palheteira plants had a height of 42.2 cm and a diameter of 9.1 mm, 70 days after transplanting. These values exceeded the values of this experiment, where the mean height was 35.4 cm in S_e and the mean root collar diameter 4.6 mm in S_1c.

According to Gomes and Paiva (2006)GOMES, J.M.; PAIVA, H.N. Viveiros florestais. Viçosa, MG: Universidade Federal de Viçosa, 2006. 116p., the lower the SDW/RDW ratio, the better the plant quality. In this experiment, the means of ice-cream-bean, orelha-de-macaco and palheteira plants had lower SDW/RDW ratios than the 1.66 of the palheteira saplings cultivated in agricultural soil by Souza et al. (2007)SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007..

At harvest, the DQI of most plants of the three species under study was higher than the minimum required for field planting, except in the case of orelha-de-macaco in S_e. According to Hunt (1990), and cited by Chaves and Paiva (2004)CHAVES, A.S.; PAIVA, H.N. Influência de diferentes períodos de sombreamento sobre a qualidade de mudas de fedegoso (Senna macranthera (Collad.) Irwin et Barn. Scientia Forestalis, v.65, n.1, p.22-29, 2004., 0.20 is the minimum DQI recommended for Picea abies and Pseudotsuga menziesii seedlings

Specifically in the case of palheteira, calculating the DQI with data published by Souza et al. (2007)SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007. for seedlings cultivated in agricultural soil for 70 days, the DQI of 3.9 was almost 10 times higher than the mean DQI of 0.34 of the palheteira saplings of this experiment with ice-cream bean, orelha de macaco e palheteira. For the results of this experiment with palheteira in charcoal-enriched substrate, this also shows that after 90 days, the DQI had not reached the potential of this species. Moreover, the DQI values for palheteira found by Souza et al. (2007)SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007. also exceeded the values of ice-cream-bean and orelha-de-macaco in all treatments. Possibly, the explanation for the difference in the quality of palheteira seedlings was that Souza et al. (2007)SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007. used no restriction of the natural luminosity in the greenhouse, since a slight level of chlorosis was observed on the seedlings during the experiment.

The higher NN and NDW in ice-cream-bean and NDW in palheteira on the substrates with charcoal compared to S_e were possibly a response to the lower entries of N in the type of organic material used in the substrate. It is known that N uptake in noduliferous legumes consists of the sum of N₂ fixed by symbiotic processes and N mineralized in the soil, resulting from the decomposition of the OM pools. The evidence is that, as the N₂-fixing symbiotic process is a restorative property of the ecosystem in response to disturbances and is weaker in more favorable environments, the chemical properties of charcoal stimulated nodulation more than manure.

The results of the evaluation of nodulation of the three species allows the statement that manure in the substrate composition inhibited nodulation, similarly as the symbiontic process reported by Vieira et al. (2011)VIEIRA, E.P.; SOUZA, L.A.G. Inoculação com rizóbios em mudas de acapu do igapó e saboarana. Revista de Ciências Agrárias, v.54, n. 1, p.54-62, 2011. was inhibited by the supply of mineral N. The full nodulation of the seedlings is interesting since under field conditions, they may be more autonomous in terms of N uptake.

In the case of ice-cream-bean and palheteira, the leaf N content in this experiment was higher than the mean reported by Souza et al (2007)SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007. for Leucaena leucocephala with 21.4 g kg^-1, and similar to the mean of orelha-de-macaco. With regard to shoot N accumulation, Vieira et al (2011)VIEIRA, E.P.; SOUZA, L.A.G. Inoculação com rizóbios em mudas de acapu do igapó e saboarana. Revista de Ciências Agrárias, v.54, n. 1, p.54-62, 2011. reported a mean of 38.3 mg plant^-1 for Swartzia argentea, which is lower than most values of shoot N content determined in ice-cream-bean, palheteira and orelha-de-macaco.

The absence of differences in growth and nodulation improvement of ice-cream-bean and palheteira plants in the charcoal-containing substrates suggested that charcoal could be used as a substitute for manure without affecting the seedling quality (Table 3). On the other hand, for orelha-de-macaco plants, the growth and nodulation traits were more favorable in S and S_2c, also suggesting the possibility of substitution of manure by charcoal or only the omission of manure.

5. CONCLUSION

The growth of ice-cream-bean and palheteira seedlings was not altered and nodulation was favored by the use of charcoal as substitute of manure in the 3:2:0.5 substrate of clay soil, sand and manure. In the substrates of clay soil and sand (3:2) and of clay soil, sand and charcoal (2.5:2:1), the growth and nodulation of orelha-de-macaco seedlings was better than in the 3:2:0.5 clay soil, sand and manure mixture. Thus, the results suggest that the substitution of manure by charcoal favors the quality of the three studied species.

6. REFERENCES

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CENTENO, A.J. Curso de estatística aplicada à biologia Goiânia: UFG, 1990. 188p.
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CHIDUMAYO, E.N. Effects of wood carbonization on soil and initial development of seedlings in miombo woodland, Zambia. Forest Ecology and Management, v.70, n.1, p.353-357, 1994.
CUNHA, A.O.; ANDRADE, L.A.; BRUNO, R.L.A.; SILVA, J.A.L.;SOUZA, V.C. Efeitos de substratos e das dimensões dos recipientes na qualidade das mudas de Tabebuia impertiginosa (Mart. Ex D.C.) Standl. Revista Árvore, v.29, n.4, p.507-516, 2006.
DICKSON, A.; LEAF, A.; HOSNER, J.F. Quality appraisal of white spruce and white pine seedling stock in nurseries. Forestry Chronicle, v.36, p.10-13, 1960.
EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Manual de métodos de análise de solo Rio de Janeiro: Centro Nacional de Pesquisa de Solos, 1997. 212p.
FONSECA, E.P.; VALERI, S.V.; MIGLIORANZA, E.; FONSECA, N.A.N.; COUTO, L. Padrão de qualidade de mudas de Trema micrantha (L.) Blume, produzidas sob diferentes períodos de sombreamento. Revista Árvore, v.26, n.4, p.515-523, 2002.
GLASER, B.; HAUMAIER, L.; GUGGENBERGER, G.; ZECH, W. The Terra Preta phenomenon - a model for sustainable agriculture in the humid tropics. Naturwissenschaften, v.88, n.1, p.37-41, 2001.
GOMES, J.M.; PAIVA, H.N. Viveiros florestais Viçosa, MG: Universidade Federal de Viçosa, 2006. 116p.
HUNGRIA, M. Coleta de nódulos e isolamento de rizóbios. In: HUNGRIA, M.; ARAÚJO, R.S. (Ed.) Manual de métodos empregados em estudos de microbiologia agrícola Brasília: Empresa Brasileira de Pesquisa Agropecuária, 1994. p.45-59.
INSTITUTO NACIONAL DE PESQUISAS ESPACIAIS - INPE. [acessado em: jan. 28, 2013]. Disponível em: http://www.Cptec.inpe.br/clima/monit/monitor_brasil.shtml
» http://www.Cptec.inpe.br/clima/monit/monitor_brasil.shtml
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SANTOS, R.C.; CARNEIRO, A.C.O.; PIMENTA, A.S.; CASTRO, R.V.O.; MARINHO, I.V.; TRUGILHO, P.F.; ALVES, I.C.N.; CASTRO, A.F.N.M. Potencial energético da madeira de espécies oriundas de plano de manejo florestal no estado do Rio Grande do Norte. Ciência Florestal, v.23, n.2, p.491-502, 2013
SCHUMACHER, M.V.; CALDEIRA, M.V.W.; OLIVEIRA, E.R.V.; PIROLI, E.L. Influência do vermicomposto na produção de mudas de Eucalyptus grandis hillex maiden. Ciência Florestal, v.11, n.2, p.121-130, 2001.
SOUCHIE, F.F.; MARIMON JUNIOR, B.H.; PETTER, F.A.; MADARI, B.E.; MARIMON, B.S.; LENZA, E. Carvão pirogênico como condicionante para substrato de mudas de Tachigali vulgaris L.G.Silva & H.C.Lima. Ciência Florestal, v.21, n.4, p. 811-821, 2011.
SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007.
TRYON, E.H. Effect of charcoal on certain physical, chemical, and biological properties of forest soils. Ecological Monographs, v.18, n.1, p.81-115, 1948.
UCHIDA, T.; CAMPOS, M.A.A. Influência do sombreamento no crescimento de mudas de cumaru (Dipteryx odorata (Aubl.) Willd. - Fabaceae), cultivadas em viveiro. Acta Amazônica, v.30, n.1, p.107-114, 2000.
VIEIRA, E.P.; SOUZA, L.A.G. Inoculação com rizóbios em mudas de acapu do igapó e saboarana. Revista de Ciências Agrárias, v.54, n. 1, p.54-62, 2011.
ZANETTI, M.; CAZETTA, J.O.; MATTOS JUNIOR, D.; CARVALHO, S.A. Uso de subprodutos de carvão vegetal na formação de porta-enxerto limoeiro 'cravo' em ambiente protegido. Revista Brasileira de Fruticultura, v.25, n.3, p.508-512, 2003.

Publication Dates

Publication in this collection
Nov-Dec 2016

History

Received
24 Oct 2013
Accepted
24 Oct 2016

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] BERNARDINO, D.C.S.; PAIVA, H.N.; NEVES, J.C.L.; GOMES, J.M.; MARQUES, V.B. Crescimento e qualidade de mudas de Anadenanthera macrocarpa (Benth.) Brenan em resposta à saturação por bases do substrato. Revista Árvore, v.29, n.6, p.863-870, 2005.

[2] CENTENO, A.J. Curso de estatística aplicada à biologia Goiânia: UFG, 1990. 188p.

[3] CHAVES, A.S.; PAIVA, H.N. Influência de diferentes períodos de sombreamento sobre a qualidade de mudas de fedegoso (Senna macranthera (Collad.) Irwin et Barn. Scientia Forestalis, v.65, n.1, p.22-29, 2004.

[4] CHIDUMAYO, E.N. Effects of wood carbonization on soil and initial development of seedlings in miombo woodland, Zambia. Forest Ecology and Management, v.70, n.1, p.353-357, 1994.

[5] CUNHA, A.O.; ANDRADE, L.A.; BRUNO, R.L.A.; SILVA, J.A.L.;SOUZA, V.C. Efeitos de substratos e das dimensões dos recipientes na qualidade das mudas de Tabebuia impertiginosa (Mart. Ex D.C.) Standl. Revista Árvore, v.29, n.4, p.507-516, 2006.

[6] DICKSON, A.; LEAF, A.; HOSNER, J.F. Quality appraisal of white spruce and white pine seedling stock in nurseries. Forestry Chronicle, v.36, p.10-13, 1960.

[7] EMPRESA BRASILEIRA DE PESQUISA AGROPECUÁRIA - EMBRAPA. Manual de métodos de análise de solo Rio de Janeiro: Centro Nacional de Pesquisa de Solos, 1997. 212p.

[8] FONSECA, E.P.; VALERI, S.V.; MIGLIORANZA, E.; FONSECA, N.A.N.; COUTO, L. Padrão de qualidade de mudas de Trema micrantha (L.) Blume, produzidas sob diferentes períodos de sombreamento. Revista Árvore, v.26, n.4, p.515-523, 2002.

[9] GLASER, B.; HAUMAIER, L.; GUGGENBERGER, G.; ZECH, W. The Terra Preta phenomenon - a model for sustainable agriculture in the humid tropics. Naturwissenschaften, v.88, n.1, p.37-41, 2001.

[10] GOMES, J.M.; PAIVA, H.N. Viveiros florestais Viçosa, MG: Universidade Federal de Viçosa, 2006. 116p.

[11] HUNGRIA, M. Coleta de nódulos e isolamento de rizóbios. In: HUNGRIA, M.; ARAÚJO, R.S. (Ed.) Manual de métodos empregados em estudos de microbiologia agrícola Brasília: Empresa Brasileira de Pesquisa Agropecuária, 1994. p.45-59.

[12] INSTITUTO NACIONAL DE PESQUISAS ESPACIAIS - INPE. [acessado em: jan. 28, 2013]. Disponível em: http://www.Cptec.inpe.br/clima/monit/monitor_brasil.shtml
» http://www.Cptec.inpe.br/clima/monit/monitor_brasil.shtml

[13] LORENZI, H. Árvores brasileiras Nova Odessa: Instituto Plantarum, 2002. 381p.

[14] MAJOR,J.; DITOMMASO, A.; LEHMANN, J.; FALCÃO, N.P.S. Weed dynamics on Amazonian Dark Earth and adjacent soils of Brazil. Agriculture, Ecosystems and Environment, v.11, p.1-12, 2005.

[15] MENDONÇA, E.S.; MATOS, E.S. Matéria orgânica do solo: Método de análises Viçosa, MG: Universidade Federal de Viçosa, 2005.107p.

[16] MOREIRA, A. Fertilidade, matéria orgânica e substâncias húmicas em solos antropogênicos da Amazônia Ocidental. Bragantia, v.66, p.307-315, 2007.

[17] OLIVEIRA, D.M.; FALCÃO, N.P.S.; SOUZA, L.A.G. Efeito do resíduo de carvão vegetal e pó de serra no crescimento vegetativo e na nodulação do feijão caupi (Vigna Unguiculata L. Walp) em Latossolo Amarelo distrófico da Amazônia Central. In: REUNIÃO CIENTÍFICA DA REDE CTPETRO AMAZÔNIA, 3., 2010, Manaus. Anais... Manaus: Instituto Nacional de Pesquisas da Amazônia, 2010. p.1-11.

[18] PORTELA, R.C.Q.; SILVA, I.L.; PINÃ-RODRIGUES, F.C.M. Crescimento inicial de mudas de Clitoria fairchildiana Howard e Peltophorum dubium (Sprenge) Taub em diferentes condições de sombreamento. Ciência Florestal, v.11, n.2, p.163-170, 2001.

[19] RONDON, M.A., LEHMANN, J.; RAMÍREZ, J.; HURTADO, M. Biological nitrogen fixation by common beans (Phaseolus vulgaris L.) increases with bio-char additions. Biology Fertility Soils, v.43, p.699-708, 2007.

[20] SANTOS, R.C.; CARNEIRO, A.C.O.; PIMENTA, A.S.; CASTRO, R.V.O.; MARINHO, I.V.; TRUGILHO, P.F.; ALVES, I.C.N.; CASTRO, A.F.N.M. Potencial energético da madeira de espécies oriundas de plano de manejo florestal no estado do Rio Grande do Norte. Ciência Florestal, v.23, n.2, p.491-502, 2013

[21] SCHUMACHER, M.V.; CALDEIRA, M.V.W.; OLIVEIRA, E.R.V.; PIROLI, E.L. Influência do vermicomposto na produção de mudas de Eucalyptus grandis hillex maiden. Ciência Florestal, v.11, n.2, p.121-130, 2001.

[22] SOUCHIE, F.F.; MARIMON JUNIOR, B.H.; PETTER, F.A.; MADARI, B.E.; MARIMON, B.S.; LENZA, E. Carvão pirogênico como condicionante para substrato de mudas de Tachigali vulgaris L.G.Silva & H.C.Lima. Ciência Florestal, v.21, n.4, p. 811-821, 2011.

[23] SOUZA, L.A.G.; BEZERRA NETO, E.; SANTOS, C.E.R.S.; STAMFORD, N.P. Desenvolvimento e nodulação natural de leguminosas arbóreas em solos de Pernambuco. Pesquisa Agropecuária Brasileira, v.42, n.2, p.207:217, 2007.

[24] TRYON, E.H. Effect of charcoal on certain physical, chemical, and biological properties of forest soils. Ecological Monographs, v.18, n.1, p.81-115, 1948.

[25] UCHIDA, T.; CAMPOS, M.A.A. Influência do sombreamento no crescimento de mudas de cumaru (Dipteryx odorata (Aubl.) Willd. - Fabaceae), cultivadas em viveiro. Acta Amazônica, v.30, n.1, p.107-114, 2000.

[26] VIEIRA, E.P.; SOUZA, L.A.G. Inoculação com rizóbios em mudas de acapu do igapó e saboarana. Revista de Ciências Agrárias, v.54, n. 1, p.54-62, 2011.

[27] ZANETTI, M.; CAZETTA, J.O.; MATTOS JUNIOR, D.; CARVALHO, S.A. Uso de subprodutos de carvão vegetal na formação de porta-enxerto limoeiro 'cravo' em ambiente protegido. Revista Brasileira de Fruticultura, v.25, n.3, p.508-512, 2003.

Treatment	Substrate mixture	Label
T 1	3:2:0.5, clay soil, sand and cattle manure	S_e
T 2	3:2, clay soil and sand	S
T 3	5.5:3.5:1, clay soil, sand and charcoal	S_1c
T 4	2.5:2:1, clay soil, sand and charcoal	S_2c
T 5	5:2:1, clay soil, sand and charcoal	S_3c

Samples⁽¹ (1) Se = clay soil, sand and cattle manure (3:2:0.5), S = clay soil and sand (3:2), S1c = clay soil, sand and charcoal (5.5:3.5:1), S2c = clay soil, sand and charcoal (2.5:2:1), S3c = clay soil, sand and charcoal (1.5:2:1), ⁾	pH H₂O	OM⁽² (2) OM = Organic matter. ⁾g kg^-1	H+Al	Ca	Mg	P	K	Fe	Zn
	pH H₂O	OM⁽² (2) OM = Organic matter. ⁾g kg^-1	—— cmol_c kg^-1 ——			————— mg kg^-1 ——————
Components
Clay soil	5.1	8.3	0.11	838	235	2.4	24	137	1.5
Sand	6.8	0.4	0	115	7	7.8	17	29	5.5
Manure	6.4	50.6	0	3340	372	2915	1076	81	52.9
Charcoal	4.4	179	2.68	3245	334	35.5	510	10	7.9
Substrate mixtures
S_e	6.2	30.6	0	884	220	110	93	151	11.1
S	5.9	20.0	0.06	813	160	6.0	33	138	5.1
S_1c	5.4	16.4	0.06	411	112	3.2	51	117	4.8
S_2c	6.0	25.1	0.08	472	138	5.4	47	134	4.4
S_3c	5.6	27.3	0.14	770	174	15.6	102	112	6.2

S.V.⁽² (2) S.V. = Source of variation; Se = clay soil, sand and cattle manure (3:2:0.5); S = clay soil and sand (3:2); S1c = clay soil, sand and charcoal (5.5:3.5:1); S2c = clay soil, sand and charcoal (2.5:2:1); S3c = clay soil, sand and charcoal (1.5:2:1); ⁾	H⁽³ (3) H = Height; ⁾	D⁽⁴ (4) D = Root collar diameter; ⁾	SDW⁽⁵ (5) SDW = Shoot dry weight; ⁾	RDW⁽⁶ (6) RDW = Root dry weight; ⁾	SDW/RDW⁽⁷ (7) SDW/RDW = ratio shoot dry weight by root dry weight; ⁾	DQI⁽⁸ (8) DQI = Dickson quality index. ⁾
	(cm)	(mm)	(g)
Inga edulis
S_e	30.2 a	4.1 a	3.01 a	0.97 a	3.02 a	0.38 a
S	29.2 a	4.0 a	3.10 a	0.97 a	3.43 a	0.39 a
S_1c	28.2 a	3.9 a	3.40 a	0.96 a	3.57 a	0.40 a
S_2c	28.3 a	3.8 a	3.30 a	0.91 a	3.79 a	0.38 a
S_3c	27.4 a	3.7 a	3.15 a	1.17 a	2.71 a	0.43 a
CV (%)	19.73	13.45	32.32	28.74	29.91	29.68
F test	0.36 ns	1.28 ns	0.22 ns	1.17 ns	2.55 ns	0.35 ns
Enterolobium schomburgkii
S_e	9.6 b	1.6 c	0.37 c	0.22 b	1.91 ab	0.08 b
S	24.4 a	3.2 a	2.29 a	0.92 a	2.66 a	0.32 a
S_1c	19.6 a	2.8 ab	1.50 b	1.04 a	1.48 b	0.30 a
S_2c	19.8 a	2.7 ab	1.88 ab	0.87 a	2.25 ab	0.29 a
S_3c	18.9 a	2.6 b	1.79 ab	0.78 a	2.34 ab	0.27 a
CV (%)	24.46	15.64	36.16	34.55	35.84	34.75
F test	14.38 *	21.21 *	16.49 *	14.69 *	3.49 *	12.17 *
Clitoria fairchildiana
S_e	35.4 a	4.4 a	2.66 a	1.04 a	2.93 a	0.34 a
S	34.6 a	4.5 a	2.41 a	0.90 a	2.73 a	0.32 a
S_1c	34.7 a	4.6 a	3.10 a	1.20 a	2.73 a	0.42 a
S_2c	35.1 a	4.5 a	3.33 a	1.19 a	2.91 a	0.43 a
S_3c	34.9 a	4.4 a	2.64 a	1.01 a	2.51 a	0.34 a
CV (%)	14.71	10.00	31.13	28.74	29.35	26.65
F test	0.05 ns	0.23 ns	1.79 ns	1.63 ns	0.31 ns	2.52 ns

S.V.⁽² (2) S.V. = Source of variation; Se = clay soil, sand and cattle manure (3:2:0.5); S = clay soil and sand (3:2); S1c = clay soil, sand and charcoal (5.5:3.5:1); S2c = clay soil, sand and charcoal (2.5:2:1); S3c = clay soil, sand and charcoal (1.5:2:1); ⁾	NN⁽³ (3) Nodule number; ⁾	NDW⁽⁴ (4) NDW = Nodule dry weight; ⁾	Leaf N	CNPS⁽⁵ (5) CNPS = Cumulative N in plant shoots. ⁾
		(mg)	(g kg^-1)	(mg plant^-1)
Inga edulis
Se	44 b	46 b	35.99 a	104.11 a
S	101 a	89 ab	32.88 a	74.84 a
S1c	97 a	104 a	35.30 a	102.48 a
S2c	104 a	114 a	34.93 a	89.09 a
S3c	83 a	74 ab	34.53 a	85.74 a
CV (%)	34.37	25.69	8.20	17.83
F test	5.18*	4.29*	0.66 ns	2.25 ns
Enterolobium schomburgkii
Se	0 c	0 c	22.04 a	11.41 c
S	28 a	46 a	22.96 a	52.40 a
S1c	8 b	13 bc	21.97 a	33.30 b
S2c	17 ab	44 a	22.80 a	42.76 ab
S3c	14 ab	38 ab	22.12a	46.94 ab
CV (%)	65.08	29.48	11.91	19.94
F test	9.87*	10.46*	0.87 ns	18.69 *
Clitoria fairchildiana
Se	20 a	13 b	33.74 a	54.39 ab
S	33 a	44 a	33.90 a	53.25 b
S1c	32 a	44 a	34.41 a	67.61 ab
S2c	32 a	51 a	31.75 a	58.53 ab
S3c	33 a	50 a	34.72 a	70.30 a
CV (%)	35.44	25.20	7.89	12.41
F test	1.14 ns	5.79 *	0.77 ns	4.51 *

Brasil

Brasil

EFFECT OF CHARCOAL -ENRICHED SUBSTRATE ON SEEDLINGS OF RHIZOBIUM-INOCULATED LEGUME TREES

ADIÇÃO DE CARVÃO NO SUBSTRATO DE FORMAÇÃO DE MUDAS DE LEGUMINOSAS ARBÓREAS INOCULADAS COM RIZÓBIOS

ABSTRACT

RESUMO

1. INTRODUCTION

2. METHODOLOGY

2.1 Description of the experiment

2.2 Seedling cultivation

2.3 Harvesting of seedlings and laboratory analysis

2.4 Data analysis and experimental design

3. RESULTS

4. DISCUSSION

5. CONCLUSION

6. REFERENCES

Publication Dates

History