SPATIALITY OF SOIL CHEMICAL ATTRIBUTES IN A BANANA CULTIVATION AREA IN WEST BAHIA

OLIVEIRA, BARBEMILE DE ARAÚJO DE; CAMPOS, LILIANE PEREIRA; MATIAS, SAMMY SIDNEY ROCHA; SILVA, TAMIRES SOARES DA; GUALBERTO, ADRIANO VENICIÚS SANTANA

doi:10.1590/1983-21252021v34n118rc

ABSTRACT

Irrigated fruit growing in the São Francisco Valley has been standing out in the Northeast region of Brazil and the incorrect management of fertilization has caused problems of physical and / or chemical degradation of the soil. The work aimed to evaluate the spatial variability of the chemical attributes of a Latossolo Vermelho-Amarelo (Oxisol) grown with banana (Musa spp). The study was carried out in the irrigated perimeter of Nupeba in Riachão das Neves / BA. In an area cultivated for 18 years with silver banana fertigated by micro sprinkling. In April 2017 simple soil samples were collected at depths of 0 -0.20 m and 0.20 -0.40 m, from an experimental grid consisting of 40 georeferenced points and spaced every 10 meters. The soil samples determined: pH (H₂O); Organic carbon; Phosphorus (P); Potassium (K⁺); Calcium (Ca²⁺); Magnesium (Mg²⁺) and Potential acidity (H + Al) and the sum of bases (BS), cation exchange capacity (CEC) and base saturation (V%) were calculated. The results of the analyses were evaluated using descriptive statistics and the geostatistics technique. The descriptive analysis identified the normality of the data. The spatial variability was confirmed, allowing the making of maps. The analyzed area has low fertility (V <55%) and the inadequate management of soil correction and fertilization can reduce the availability of nutrients for the implanted crop, making the soil susceptible to degradation with the use of irrigation. The distribution maps allow the visualization of the area, allowing the application of inputs with varying rates, aiming at homogenizing the soil fertility.

Keywords:
Musa spp; Distribution maps; Soil fertility

RESUMO

A fruticultura irrigada no Vale do São Francisco vem se destacando na região Nordeste do Brasil e o manejo incorreto da adubação tem proporcionado problemas de degradação física e/ou química do solo. O trabalho teve como objetivo avaliar a variabilidade espacial dos atributos químicos de um Latossolo Vermelho -Amarelo cultivado com banana (Musa spp). O estudo foi realizado no perímetro irrigado de Nupeba em Riachão das Neves/BA. Em uma área cultivada por 18 anos com banana prata fertirrigada por microaspersão. Em abril de 2017 coletou-se amostras simples de solo nas profundidades de 0-0,20 m e de 0,20-0,40 m, a partir de uma malha experimental constituída de 40 pontos georreferenciados e distanciados a cada 10 metros. Nas amostras de solo foram determinados: pH (H₂O); Carbono orgânico; Fósforo (P); Potássio (K⁺); Cálcio (Ca²⁺); Magnésio (Mg²⁺) e Acidez potencial (H+Al) e calculados a soma de bases (SB), capacidade de troca catiônica (CTC) e saturação por bases (V%). Os resultados das análises foram avaliados por meio da estatística descritiva e a técnica da geoestatistica. A análise descritiva identificou a normalidade dos dados. A variabilidade espacial foi confirmada, permitindo a confecção de mapas. A área analisada possui baixa fertilidade (V<55%) e o manejo inadequado de correção e adubação do solo podem reduzir a disponibilidade dos nutrientes para a cultura implantada, tornando o solo passível de degradação com o uso da irrigação. Os mapas de distribuição permitem a visualização da área, possibilitando a aplicação de insumos com taxa variada, visando à homogeneização da fertilidade do solo.

Palavras-chave:
Musa spp; Mapas de distribuição; Fertilidade do solo

INTRODUCTION

Fruit production in Brazil has a volume of 40.5 million tons (GERUM et al., 2019GERUM, A. F. A. A. et al. Fruticultura Tropical: potenciais riscos e seus impactos. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2019. 28 p.), being considered the third world fruit producer, behind only China and India, this volume represents 5% of the world fruit crop production (FAO, 2016FAO. Food and Agriculture Organization of the United Nations. Production, 2016. Disponível em: <http://www.fao.org/faostat/en/#data/QC>. Acesso em: 15 jan. 2020.
http://www.fao.org/faostat/en/#data/QC... ). The Northeastern region of Brazil is responsible for 27% of this production and the State of Bahia (13%) is the second largest Brazilian producer, behind São Paulo (40%) (GERUM et al., 2019GERUM, A. F. A. A. et al. Fruticultura Tropical: potenciais riscos e seus impactos. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2019. 28 p.).

Among the fruits cultivated in Brazil, banana (Musa spp.) is in second place in production volume being responsible for 16.7% of the national production, behind only citrus (orange, lemon and tangerine) that represent 48.2% of the national production. However, banana cultivation under tropical or semi-arid climate conditions requires supplementary irrigation to rains because evapotranspiration is higher than precipitation. Efficient irrigation management is crucial to obtain high yields in agricultural fruit production (FERREIRA et al., 2016FERREIRA, L. L. N. et al. Spatial variability of available water and micro-sprinkler irrigation in cambisol. Revista Ceres, 63: 782-788, 2016.; GERUM et al., 2019GERUM, A. F. A. A. et al. Fruticultura Tropical: potenciais riscos e seus impactos. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2019. 28 p.).

However, the areas submitted to the irrigated perimeters have presented problems of soil degradation (physical and chemical), resulting from inadequate soil management (DANTAS et al., 2012DANTAS, J. D. N. et al. Qualidade do solo sob diferentes usos e manejos no perímetro irrigado de Jaguaribe-Apodi, Brasil. Revista Brasileira de Engenharia Agrícola e Ambiental, 16: 1012-1022, 2012.). Irrigation provides adequate water for plant growth, so that they can express their full genetic potential. However, irrigation generally results in excessive water application in some planting areas and insufficient water in others due to the non-uniformity of the cultivated areas, thus being able to directly influence the productivity of irrigated crops and increase the costs of agricultural projects (FERREIRA et al., 2016FERREIRA, L. L. N. et al. Spatial variability of available water and micro-sprinkler irrigation in cambisol. Revista Ceres, 63: 782-788, 2016.).

Studies by Lima et al. (2015)LIMA, F. V. et al. Variabilidade espacial de atributos físicos do solo em área de encosta sob processo de degradação. Revista Caatinga, 28: 53-63, 2015. and Vian et al. (2016)VIAN, A. L. et al. Variabilidade espacial da produtividade de milho irrigado e sua correlação com variáveis explicativas de planta. Ciência Rural, 46: 464-471, 2016., showed that the determination of soil variability using technological tools such as geostatistics is essential for the correct soil-plant-atmosphere interaction, as it allows different application of water according to the needs of each area (management specific), favoring yield optimization, increasing the efficiency of inputs, maximizing benefits and reducing costs.

According to Matias et al. (2015)MATIAS, S. S. R. et al. Variabilidade espacial dos atributos do solo em duas áreas de manejo convencional no Cerrado piauiense. Revista de Ciências Agrárias, 58: 217-227, 2015., soil variability information is essential to plan and implement more efficient, profitable and environmentally sustainable agriculture, with regard to the use of correctives and fertilizers, because it allows to apply in the right place and appropriate time the quantities necessary for agricultural production, making it essential to assist in the efficient management of soil and water.

The use of geostatistics can enhance the increase in Brazilian fruit production, due to the ability to determine specific management zones for effective correction of crop needs in the management of soil and water (MATIAS et al., 2019MATIAS, S. S. R. et al. Recomendação de calagem com base na variabilidade espacial de atributos químicos do solo no Cerrado brasileiro. Revista de Ciências Agrárias, 42: 896-907, 2019.). However, to outline a specific management area, it is necessary to carry out joint analyses of the attributes that affect crop productivity (CORDOBA et al., 2013CÓRDOBA, M. et al. Subfield management class delineation using cluster analysis from spatial principal components of soil variables. Computers and Electronics in Agriculture, 97: 6-14, 2013.; YAO et al., 2014YAO, R. J. et al. Determination of site-specific management zones using soil physico-chemical properties and crop yields in coastal reclaimed farmland. Geoderma, 232: 381-393, 2014.; HAGHVERDI et al., 2015HAGHVERDI, A. et al. Perspectives on delineating management zones for variable rate irrigation. Computers and Electronics in Agriculture, 117: 154-167, 2015.), that vary vertically and horizontally across the landscape (SIQUEIRA et al., 2015SIQUEIRA, G. M. et al. Estacionariedade do conteúdo de água de um Espodossolo Humilúvico. Revista Brasileira de Engenharia Agrícola e Ambiental, 19: 439-448, 2015.).

Therefore, the present work aimed to evaluate the spatial variability of soil chemical attributes in a banana-cultivated area in the irrigated perimeter of Nupeba-Riacho Grande, western Bahia.

MATERIALS AND METHODS

The study was carried out in the Nupeba irrigated perimeter managed by the São Francisco and Parnaíba Valleys Development Company (CODEVASF, 2020CODEVASF. Companhia de Desenvolvimento dos Vales do São Francisco e do Parnaíba. Projetos Públicos de Irrigação. Disponível em: <http://www.codevasf.gov.br/principal/perimetrosirrigados/elencodeprojetos/nupeba-riacho-grande>. Acesso em: 05 jan. de 2020.
http://www.codevasf.gov.br/principal/per... ) located in the municipality of Riachão das Neves / BA (11° 44'49''S and 11° 54'23'' O, 440 m altitude), in the West of Bahia. The climate of the region, according to the current classification by Koppen cited by Alvares et al. (2013)ALVARES, C. A. et al. Koppen's climate classification map for Brazil. Meteorologische Zeitschrift, Germany, 22: 711-728, 2013., is of the Aw type, hot and semi-humid. The average annual temperature is 27°C, with an average annual rainfall of 1.000 mm and the rainy season is from October to April, with November, December and January being the rainiest months (INMET, 2020INMET. Ministério da Agricultura, Pecuária e Abastecimento. Instituto Nacional de Metereologia. Disponível em: <http://www.inmet.gov.br/portal/index.php?r=home2/index>. Acesso em: 15 jan. 2020.
http://www.inmet.gov.br/portal/index.php... ). The soil is classified as dystrophic Latossolo Vermelho-Amarelo (Oxisol), with a sandy-clay texture (SANTOS et al., 2018SANTOS, H. G. et al. Sistema Brasileiro de Classificação de Solos. 5. ed. Rio de Janeiro, RJ: Embrapa Solos, 2018. 356 p.).

A 2 hectare Cerrado area was selected and cultivated with banana trees for 18 years, the cultivar is banana type Prata, with a spacing of 2.4 m between plants and between single and double rows, respectively, 2.0 and 4.0 m, fertigated by micro sprinkling. In December/2015 the area received 2 t ha^-1 of dolomitic limestone, in addition to the following fertilizations according to the crop production cycle: biweekly fertilizations with 55 g of potassium chloride and 30 g of ammonium sulfate; monthly fertilizations 120 g of simple superphosphate. The characterization of the chemical and physical attributes of the soil collected at a depth of 0-0.20 m in January 2017 and analyzed using the methodology proposed by Donagemma et al. (2011)DONAGEMMA, G. K. et al. Manual de métodos de análise de solos. 2. ed. revisado, Rio de Janeiro, RJ: Embrapa Solos, 2011. 230 p., before the implementation of fertigation are described in Table 1 and the characterization of fertigation which started in February 2017 is in Table 2.

Thumbnail

Table 1
Result of the Chemical and physical attributes of the soil at a depth of 0-0.20 m, in an area cultivated with banana before the experiment (2017).

Thumbnail

Table 2
Data on fertigation of the banana plantation (Prata) in 2017.

In April 2017, simple deformed soil samples were collected, from a regular grid of 40 georeferenced points and spaced every 10 m, at depths of 0-0.20 m and 0.20-0.40 m, totaling 80 samples, 40 per depth. The collected soil samples were air dried, ground, macerated and passed through a 2 mm mesh sieve (TFSA) and sent for laboratory analysis.

They were analyzed, following the methodology of Donagemma et al. (2011)DONAGEMMA, G. K. et al. Manual de métodos de análise de solos. 2. ed. revisado, Rio de Janeiro, RJ: Embrapa Solos, 2011. 230 p.: pH in H₂O; calcium (Ca²⁺) and magnesium (Mg²⁺) by extraction with potassium chloride (KCl) 1 mol L^-1 and quantified in titulometry by EDTA complexometry; phosphorus (P) with Mehlich-1 extractor and colorimetric determination; potassium (K⁺) was extracted with diluted hydrochloric acid solution and determined by flame photometry; Total Organic Carbon (TOC) by hot oxidation using potassium dichromate; potential acidity (H + Al) by extraction with buffered calcium acetate solution at pH 7.0 quantified by titration with sodium hydroxide (NaOH) and phenolphthalein as an indicator; aluminum (Al³⁺) determined by extraction with NaOH in the presence of bromothymol blue as an indicator. The sum of bases (BS), cation exchange capacity (CEC) and base saturation (V) were calculated.

Statistical analysis was carried out by means of an exploratory study of the data using the MINITAB® software, the measurement of location (mean, median, minimum and maximum), the measures of variability (coefficient of variation -CV%) were calculated and the measures of central tendency (asymmetry and kurtosis), to verify the normality of the chemical attributes evaluated.

Semivariograms were obtained using the GS⁺® program (ROBERTSON, 2008ROBERTSON, G. P. GS+ geostatistics for the environmental sciences: GS+ user's guide. Plainwell: Gamma Design Software, 2008, 152 p.) and the following models were adjusted to the data: (a) spherical, (b) exponential, (c) Gaussian. From these models, attributes were predicted in areas not sampled by kriging, represented on contour maps, using the SURFER® program. The degree of spatial dependence (GDE) was classified based on the nugget effect and sill (C₀/C₀ + C₁), being considered weak above 75%, moderate between 25% and 75% and strong below 25% (CAMBARDELLA et al., 1994CAMBARDELLA, C. A. et al. Field scale variability of soil properties in central Iowa soils. Soil Science Society of American Journal, 58: 1501-1511, 1994.). In the maps of the spatial distribution of soil chemical attributes, the contents were interpreted according to the description made by Ribeiro, Guimarães and Alvarez (1999)RIBEIRO, A. C.; GUIMARÃES, P. T. G.; ALVAREZ, V. V. H. Recomendações para o uso de corretivos e fertilizantes em minas gerais: 5ª aproximação. Viçosa, MG: Comissão de Fertilidade do Solo do Estado de Minas Gerais, 1999, 359 p., described in Table 3.

Thumbnail

Table 3
Interpretation of the results of water pH analysis, phosphorus, potassium, calcium, magnesium, aluminum, hydrogen + aluminum, sum of bases, cation exchange capacity and base saturation.

RESULTS AND DISCUSSION

There is an approximation of the mean and median values for each variable, demonstrating a normal distribution of data at each depth (Table 4).

Thumbnail

Table 4
Descriptive statistics of soil chemical attributes at depths of 0-0.20 m and 0.20-0.40 m.

According to Negreiros Neto et al. (2014)NEGREIROS NETO, J. V. et al. Variabilidade espacial de atributos físico-químicos de um Latossolo Vermelho-Amarelo distrófico em sistema plantio direto. Semina: Ciências Agrárias, 35: 193-204, 2014., the data present or approximate the normal distribution when the mean, median values consist of similar values. Additionally, the values of asymmetry and kurtosis show values close to zero, confirming the normal distribution in the depths analyzed and, thus, the use of Geostatistics for this assessment is applicable (LIMA et al., 2015LIMA, F. V. et al. Variabilidade espacial de atributos físicos do solo em área de encosta sob processo de degradação. Revista Caatinga, 28: 53-63, 2015.; FERREIRA et al., 2016FERREIRA, L. L. N. et al. Spatial variability of available water and micro-sprinkler irrigation in cambisol. Revista Ceres, 63: 782-788, 2016.; MATIAS et al., 2019MATIAS, S. S. R. et al. Recomendação de calagem com base na variabilidade espacial de atributos químicos do solo no Cerrado brasileiro. Revista de Ciências Agrárias, 42: 896-907, 2019.).

Regarding the coefficient of variation (CV%), the values presented heterogeneous series, that is, with high variability in attributes except for pH, potential acidity (H + Al), sum of bases (BS), cation exchange capacity (CEC) and base saturation (V%). To Bottega et al. (2013)BOTTEGA, E. L. et al. Variabilidade espacial de atributos do solo em sistema de semeadura direta com rotação de culturas no cerrado brasileiro. Revista Ciência Agronômica, 44: 1-9, 2013., the variability of chemical attributes is a representation of the interaction of formation processes and management practices carried out in the soil, such as the application of correctives and fertilizers and probably, due to this, the CV% values for these variables were greater than 35%.

The asymmetry coefficient is used to characterize how and how much the frequency distribution deviates from the symmetry. If the value found for this coefficient is zero, the distribution is symmetric, when it is positive, the distribution is asymmetric on the right; and if negative, it is asymmetric on the left (WERNER et al., 2012WERNER, E. T. et al. Coeficiente de variação como medida da precisão em experimentos de cultura de tecidos de plantas. Plant Cell Culture & Micropropagation, 8: 27-36, 2012.). Thus, the attribute H + Al showed an asymmetry on the left at both depths (-0.01; -0.22) and most attributes showed an asymmetric distribution on the right, between the values 0.12 and 1.68 (Table 4). This result, in general, demonstrates that the frequency and distribution is of the normal type, in agreement with those observed by other authors (DANTAS et al., 2012DANTAS, J. D. N. et al. Qualidade do solo sob diferentes usos e manejos no perímetro irrigado de Jaguaribe-Apodi, Brasil. Revista Brasileira de Engenharia Agrícola e Ambiental, 16: 1012-1022, 2012.; LIMA et al., 2015LIMA, F. V. et al. Variabilidade espacial de atributos físicos do solo em área de encosta sob processo de degradação. Revista Caatinga, 28: 53-63, 2015.; CARNEIRO et al., 2016CARNEIRO, J. S. S. et al. Diagnóstico e manejo da variabilidade espacial da fertilidade do solo no cerrado do Piauí. Revista Ciência Agroambiental, 14: 11-21, 2016.; MATIAS et al ., 2019MATIAS, S. S. R. et al. Recomendação de calagem com base na variabilidade espacial de atributos químicos do solo no Cerrado brasileiro. Revista de Ciências Agrárias, 42: 896-907, 2019.) who studied spatial variability through soil attributes.

Kurtosis coefficients are used to assess whether the data adopt a normal distribution. According to Negreiros Neto et al. (2014)NEGREIROS NETO, J. V. et al. Variabilidade espacial de atributos físico-químicos de um Latossolo Vermelho-Amarelo distrófico em sistema plantio direto. Semina: Ciências Agrárias, 35: 193-204, 2014., kurtosis should preferably be null, but values between +2 and -2 can be accepted. It was observed that the kurtosis values were within the limits considered acceptable as mentioned above, except for the Ca analyzed at a depth of 0.20-0.40 m (3.29). Possibly the irregular replacement of dolomitic limestone in the area may have influenced this result (Table 4).

The adjustment parameters of the semivariograms identified the spatial dependence (Table 5). The Gaussian and spherical models were the best adjusted, with the exception of BS in the first depth (0-0.20 m) and V% in the second depth (0.20-0.40 m), which adjusted to the exponential model.

Thumbnail

Table 5
Estimated models and parameters of semivariograms adjusted for soil Chemical attributes at depths of 0-0.20 m and 0.20-0.40 m.

Regarding the degree of spatial dependence (GDE%), obtained by analyzing the C₀ / (C₀ + C₁) x 100 ratio, it showed strong dependence for all attributes, with the exception of TOC (38.54%) and H + Al (30.52%), both in the first depth and BS (46.57%) in the second depth (Table 5), all classified as moderate. Therefore, the distributions of chemical attributes in space are not random, since all presented moderate or strong values for the degree of spatial dependence. The strong spatial dependence obtained in the attributes is intensely influenced by intrinsic soil properties, such as texture and mineralogy (CAMBARDELLA et al., 1994CAMBARDELLA, C. A. et al. Field scale variability of soil properties in central Iowa soils. Soil Science Society of American Journal, 58: 1501-1511, 1994.; MATIAS et al., 2015MATIAS, S. S. R. et al. Variabilidade espacial dos atributos do solo em duas áreas de manejo convencional no Cerrado piauiense. Revista de Ciências Agrárias, 58: 217-227, 2015.; SIQUEIRA et al., 2015SIQUEIRA, G. M. et al. Estacionariedade do conteúdo de água de um Espodossolo Humilúvico. Revista Brasileira de Engenharia Agrícola e Ambiental, 19: 439-448, 2015.).

The range between the evaluated attributes has values between: pH (18.18 m) and H + Al (95.90 m), which correspond to the areas considered homogeneous. The reach values are influenced by agronomic practices (correction, fertilization, crop treatment, irrigation and harvesting), as it aims to homogenize the cultivation area (CARNEIRO et al., 2016CARNEIRO, J. S. S. et al. Diagnóstico e manejo da variabilidade espacial da fertilidade do solo no cerrado do Piauí. Revista Ciência Agroambiental, 14: 11-21, 2016., FERREIRA et al., 2016FERREIRA, L. L. N. et al. Spatial variability of available water and micro-sprinkler irrigation in cambisol. Revista Ceres, 63: 782-788, 2016.; MATIAS et al., 2019MATIAS, S. S. R. et al. Recomendação de calagem com base na variabilidade espacial de atributos químicos do solo no Cerrado brasileiro. Revista de Ciências Agrárias, 42: 896-907, 2019.). It is a parameter that must be analyzed for ensuring that all points within a circle, with the demonstrated radius, are so similar that they can be used to estimate values for any point between them, with reliability (MATIAS et al., 2015MATIAS, S. S. R. et al. Variabilidade espacial dos atributos do solo em duas áreas de manejo convencional no Cerrado piauiense. Revista de Ciências Agrárias, 58: 217-227, 2015.; SIQUEIRA et al., 2015SIQUEIRA, G. M. et al. Estacionariedade do conteúdo de água de um Espodossolo Humilúvico. Revista Brasileira de Engenharia Agrícola e Ambiental, 19: 439-448, 2015.).

The highest values of the coefficient of determination of the model adjusted to the semivariogram (R²) for the depth 0-0.20 m were observed in the exchangeable bases, K (91.6%), Ca (84.8%) and Mg (85.5%) and in the potential acidity (84.9%) of the soil. In subsurface (0.20-0.40 m), the highest values of R² were observed for P (96.8%,), TOC (81.8%) and H + Al (81.4%) respectively. The R² shows in percentage how much of the variation of the estimated values of semi-variance is explained by models, denoting that the semivariogram model meets the requirements of spatial interpolation. Similar results were reported by Paris et al. (2020)PARIS, J. O. et al. Variability and spatial correlation of soil micronutrients and organic matter with macadamia nut production. Revista Brasileira de Engenharia Agrícola e Ambiental, 24: 31-36, 2020., who evaluated soil attributes and macadamia productivity in Latosol areas and found a high degree of dependent variable by independent variables and by Vian et al. (2016)VIAN, A. L. et al. Variabilidade espacial da produtividade de milho irrigado e sua correlação com variáveis explicativas de planta. Ciência Rural, 46: 464-471, 2016., analyzing the production of maize.

The cross-validation regression coefficient (CVRC) ranged from 61.9 to 96.7% for V % and Ca at the surface depth (0-0.20 m) respectively, obtaining the lowest value for Mg (4.8 %) and the highest values for Ca and TOC (100%) at a depth of 0.20-0.40 m. Cross-validation is the method that predicts the uncertainty of data prediction, that is, it verifies the reliability of the variogram model, which will reflect on the interpolation of the data and, consequently, in the mapping by kriging (MATIAS et al., 2015MATIAS, S. S. R. et al. Variabilidade espacial dos atributos do solo em duas áreas de manejo convencional no Cerrado piauiense. Revista de Ciências Agrárias, 58: 217-227, 2015.; SIQUEIRA et al., 2015SIQUEIRA, G. M. et al. Estacionariedade do conteúdo de água de um Espodossolo Humilúvico. Revista Brasileira de Engenharia Agrícola e Ambiental, 19: 439-448, 2015.). Lundgren, Silva and Ferreira (2017)LUNDGREN, W. J. C.; SILVA, J. A. A.; FERREIRA, R. L. C. A Precisão da Estimativa do Erro da Krigagem pela Validação Cruzada. Floresta e Ambiente, 24: 124-114, 2017. evaluated several criteria and concluded that cross-validation is the appropriate method for selecting the best fit, showing that the highest CVRC values for estimating soil attributes, using kriging, present a lower error and, therefore, it is more reliable.

Based on the semivariograms, maps of the spatial distribution of the chemical attributes pH, TOC, P, K⁺, Ca²⁺, Mg²⁺, H + Al were made at depths of 0-0.20 m and 0.20-0.40 m (Figure 1). According to Vian et al. (2016)VIAN, A. L. et al. Variabilidade espacial da produtividade de milho irrigado e sua correlação com variáveis explicativas de planta. Ciência Rural, 46: 464-471, 2016. and Matias et al. (2019)MATIAS, S. S. R. et al. Recomendação de calagem com base na variabilidade espacial de atributos químicos do solo no Cerrado brasileiro. Revista de Ciências Agrárias, 42: 896-907, 2019., the construction of kriging maps allows the identification and demarcation of areas with greater and lesser variability in relation to soil attributes, aiming at the practice of the application of inputs with adequate quantities, for example, thus respecting the need of the plant. The delimitation of the areas through specific management (maps) using soil attributes enables nutrient introduction in the correct place and quantity, thereby avoiding excess and lack in certain areas (CÓRDOBA et al., 2013CÓRDOBA, M. et al. Subfield management class delineation using cluster analysis from spatial principal components of soil variables. Computers and Electronics in Agriculture, 97: 6-14, 2013.; YAO et al., 2014YAO, R. J. et al. Determination of site-specific management zones using soil physico-chemical properties and crop yields in coastal reclaimed farmland. Geoderma, 232: 381-393, 2014.; HAGHVERDI et al., 2015HAGHVERDI, A. et al. Perspectives on delineating management zones for variable rate irrigation. Computers and Electronics in Agriculture, 117: 154-167, 2015.).All variables analyzed showed variability, with the highest values in the soil surface depth of 0-0.20 m (Figure 1). It was observed that the pH had variations between very high acidity (<4.5) and average acidity (5.1-6.0), with the banana growing better in soils with pH between 5.5 and 6.5 (RIBEIRO; GUIMARÃES; ALVAREZ, 1999RIBEIRO, A. C.; GUIMARÃES, P. T. G.; ALVAREZ, V. V. H. Recomendações para o uso de corretivos e fertilizantes em minas gerais: 5ª aproximação. Viçosa, MG: Comissão de Fertilidade do Solo do Estado de Minas Gerais, 1999, 359 p.; GERUM et al., 2019GERUM, A. F. A. A. et al. Fruticultura Tropical: potenciais riscos e seus impactos. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2019. 28 p.). Higher pH values at the surface (0-0.20 m) than at the depth (0.20-0.40 m) were also verified by Pereira et al. (2019)PEREIRA, V. G. M. F. et al. Irrigação e fertirrigação no desenvolvimento de eucalipto. Ciência Florestal, 29: 1100-1114, 2019. working in an irrigated perimeter area, stating that this acidity was probably due to fertigation, in addition to the clayey texture of the soil that makes corrective leaching difficult and the dolomitic limestone applied in the area without considering soil spatiality.

Figure 1
Maps of the spatial distribution of chemical attributes, pH, TOC, P, K⁺, Ca²⁺, Mg²⁺, H+Al at depths of 0-0.20 m and 0.20-0.40 m, in the irrigated banana crop area implanted 18 years ago.

The TOC contents (between 0.1 g kg^-1 and 1.4 g kg^-1) remained similar between the depths because they were associated with the constant replacement of labile organic material, which may have favored the increase in the variability of the carbon stock at a depth of 0.20-0.40 m (Figure 1). Despite the incorporation of organic residues from the banana crop itself at each cycle, the TOC contents for both depths were low, suggesting that carbon was in the process of cycling. It has been reported that there is accelerated decomposition of organic material from banana (BORGES; SOUZA, 2010BORGES, A. L.; SOUZA, L. S. Recomendação de adubação e calagem para bananeira. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2010. 5 p.).

At a depth of 0-0.20 m, it was observed that the P levels varied between 16.98 and 185.21 mg dm^-3 (Figure 1). This result must be associated with constant monthly mineral fertilizations of simple superphosphate, according to the needs of the crop. At a depth of 0.20-0.40 m it presented levels between very low and good (2.74 to 19.37 mg dm^-3), that is, it presented less variability within the depth because it is an element with little mobility in the soil (Figure 1). Emphasizing that phosphorus (P) is one of the nutrients most required by banana crop, according to the recommendations of Borges and Souza (2010)BORGES, A. L.; SOUZA, L. S. Recomendação de adubação e calagem para bananeira. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2010. 5 p. the P contents found in the banana area <30 mg dm^-3, indicate that the whole area needs phosphate fertilization.

The results showed lower spatial variability of K⁺ among the depths analyzed (Figure 1), presenting similar values ranging from 0.06 to 0.56 cmolc dm^-3, classified as very low and low levels. Due to the fortnightly mineral fertilizations to be launched with potassium chloride and ammonia sulfate, according to the need of the crop; it is emphasized that banana requires high concentrations of K⁺ and, in soils with <0.60 cmol_c dm^-3, potassium fertilization is required to meet the crop demand (GERUM et al, 2019GERUM, A. F. A. A. et al. Fruticultura Tropical: potenciais riscos e seus impactos. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2019. 28 p.; ALVES et al., 2019ALVES, P. F. S. et al. Soil chemical properties in banana crops fertigated with treated wastewater. Revista Caatinga, 32: 234-242, 2019.). It was observed that the depth of 0.20-0.40 m presented a reduction which can be attributed to export by the fruits, agreeing with Alves et al. (2019)ALVES, P. F. S. et al. Soil chemical properties in banana crops fertigated with treated wastewater. Revista Caatinga, 32: 234-242, 2019., where they concluded that, in an area cultivated with banana trees under irrigation with wastewater, the reduction of K⁺ in the soil can be justified by the greater extraction of the crop due to increased productivity.

The Ca in the analyzed area presented low and very good contents (0.5 to 5.8 cmol_c dm^-3) (Figure 1) from the application of correctives at the 0-0.20 m depth of the soil, and the management was complemented by the deposition of crop residues that favored the uniformity and cycling of Ca²⁺. According to Carneiro et al. (2016)CARNEIRO, J. S. S. et al. Diagnóstico e manejo da variabilidade espacial da fertilidade do solo no cerrado do Piauí. Revista Ciência Agroambiental, 14: 11-21, 2016., 94.5% of the Ca²⁺ absorbed by the banana tree returns to the soil, through the deposition of plant residues. It should be noted that Ca²⁺ is an element of low mobility within the plant and must be distributed homogeneously in the soil, as its deficiency in the soil solution in the meristemic regions of the roots can indicate serious restrictions to root development (CARNEIRO et al., 2016CARNEIRO, J. S. S. et al. Diagnóstico e manejo da variabilidade espacial da fertilidade do solo no cerrado do Piauí. Revista Ciência Agroambiental, 14: 11-21, 2016.).

Mg contents vary between very low and very good (0.0 to 5.1 cmol_c dm^-3) (Figure 1), because, due to the Ca/Mg ratio, the application of corrective agents, such as dolomitic limestone in the superficial depth, may have contributed to this result, together with the deposition of banana crop residues that favored the uniformity and cycling of Mg²⁺ and Ca²⁺. There was a decrease in levels at the 0.20-0.40 m depth, and this may be associated with greater absorption of this nutrient by banana crop, evidencing that there is a need for mg-based fertilization, as observed by Leite et al. (2013)LEITE, L. F. C. et al. Qualidade química do solo e dinâmica de carbono sob monocultivo e consórcio de macaúba e pastagem. Revista Brasileira de Engenharia Agrícola e Ambiental, 17: 1257-1263, 2013. in another irrigated perimeter.

Regarding the levels of H + Al, the values varied between medium and very good (3.79 to 10.56 cmol_c dm^-3) (Figure 1), in which, according to Leite et al. (2013)LEITE, L. F. C. et al. Qualidade química do solo e dinâmica de carbono sob monocultivo e consórcio de macaúba e pastagem. Revista Brasileira de Engenharia Agrícola e Ambiental, 17: 1257-1263, 2013., values above the average classification (Table 3), indicate that the cultivated area does not present toxicity problems, this implies that it does not hinder the development of roots and the availability of nutrients in the soil-plant relationship. It is worth mentioning that the higher the potential acidity, the greater the buffer power of the soil (the resistance of the soil to varying the pH when treated with acid or base), which may be associated with the content of organic matter or type of clay. On the other hand, in a soil with greater buffering power, it is necessary that a greater amount of limestone is added, so that there is a small change in pH, it may be due to this, that the pH values in the two depths suffer little elevation.

The values of sum of bases (BS), cation exchange capacity (CEC) and base saturation (V%) of the evaluated area showed variability at depths of 0-0.20 m and 0.20-0.40 m (Figure 2). These variables analyzed, allow a new classification of soil fertility, because it is the sum and the participatory percentage of the bases in relation to the exchange of soil cations.

Figure 2
Maps of the spatial distribution of BS, CEC and V% at depths of 0-0.20 m and 0.20-0.40 m, in the area with irrigated banana cultivation implanted 18 years ago.

The depth BS presented levels classified as low to very good (1.06 to 10.38 cmol_c dm^-3) (Figure 2). In the superficial depth it can be associated with fertilization, however at depths of 0.20-0.40 m, the values are smaller and present great variability in the whole area, resulting from the non incorporation of the dolomitic limestone (rich in bases like Ca and Mg) in depth and the possible extraction of K by the crop or loss by leaching, due to its mobility in the soil.

The CEC showed higher values at a depth of 0-0.20 m (Figure 2), values that are classified as low and very good, respectively (2.25 to 25.26 cmol_c dm^-3). The higher CEC values on the surface may be related to the higher content of organic matter from the deposition of labile material from the crop itself, in Cerrado soils, this accumulation generates negative charges (LEITE et al., 2013LEITE, L. F. C. et al. Qualidade química do solo e dinâmica de carbono sob monocultivo e consórcio de macaúba e pastagem. Revista Brasileira de Engenharia Agrícola e Ambiental, 17: 1257-1263, 2013.). The authors emphasized that it is important to analyze the CEC values with respect to fertility, as it indicates the capacity that the soil has to adsorb cations in exchangeable form, where in general, they will serve as nutrients to plants.

Base saturation (V%) showed similar values between 0-0.20 and 0.20-0.40 m depths (Figure 2), with average content classification (40.1 - 60.0%) according to Ribeiro, Guimarães and Alvarez (1999)RIBEIRO, A. C.; GUIMARÃES, P. T. G.; ALVAREZ, V. V. H. Recomendações para o uso de corretivos e fertilizantes em minas gerais: 5ª aproximação. Viçosa, MG: Comissão de Fertilidade do Solo do Estado de Minas Gerais, 1999, 359 p., whose upper limit of 60% is considered critical. It can be seen that this area has low fertility (V<50%), which means that the adopted soil management is not improving the availability of nutrients for the implanted crop. On the other hand, the spatial visualization of the distribution of V% values may allow adjusting the fertilizing and liming practices.

CONCLUSIONS

The variation of nutrients in the area is possibly a reflection of the inadequate management of soil correction and fertilization, making the soil susceptible to degradation with the use of irrigation. The distribution maps of the area, identified the places with less and greater need for correction and fertilization, enabling the application of inputs with varying rates, aiming at homogenization of soil fertility.

Paper extracted from the monography of the first author.

REFERENCES

ALVARES, C. A. et al. Koppen's climate classification map for Brazil. Meteorologische Zeitschrift, Germany, 22: 711-728, 2013.
ALVES, P. F. S. et al. Soil chemical properties in banana crops fertigated with treated wastewater. Revista Caatinga, 32: 234-242, 2019.
BORGES, A. L.; SOUZA, L. S. Recomendação de adubação e calagem para bananeira Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2010. 5 p.
BOTTEGA, E. L. et al. Variabilidade espacial de atributos do solo em sistema de semeadura direta com rotação de culturas no cerrado brasileiro. Revista Ciência Agronômica, 44: 1-9, 2013.
CAMBARDELLA, C. A. et al. Field scale variability of soil properties in central Iowa soils. Soil Science Society of American Journal, 58: 1501-1511, 1994.
CARNEIRO, J. S. S. et al. Diagnóstico e manejo da variabilidade espacial da fertilidade do solo no cerrado do Piauí. Revista Ciência Agroambiental, 14: 11-21, 2016.
CODEVASF. Companhia de Desenvolvimento dos Vales do São Francisco e do Parnaíba. Projetos Públicos de Irrigação Disponível em: <http://www.codevasf.gov.br/principal/perimetrosirrigados/elencodeprojetos/nupeba-riacho-grande>. Acesso em: 05 jan. de 2020.
» http://www.codevasf.gov.br/principal/perimetrosirrigados/elencodeprojetos/nupeba-riacho-grande
CÓRDOBA, M. et al. Subfield management class delineation using cluster analysis from spatial principal components of soil variables. Computers and Electronics in Agriculture, 97: 6-14, 2013.
DANTAS, J. D. N. et al. Qualidade do solo sob diferentes usos e manejos no perímetro irrigado de Jaguaribe-Apodi, Brasil. Revista Brasileira de Engenharia Agrícola e Ambiental, 16: 1012-1022, 2012.
DONAGEMMA, G. K. et al. Manual de métodos de análise de solos. 2. ed. revisado, Rio de Janeiro, RJ: Embrapa Solos, 2011. 230 p.
FAO. Food and Agriculture Organization of the United Nations. Production, 2016. Disponível em: <http://www.fao.org/faostat/en/#data/QC>. Acesso em: 15 jan. 2020.
» http://www.fao.org/faostat/en/#data/QC
FERREIRA, L. L. N. et al. Spatial variability of available water and micro-sprinkler irrigation in cambisol. Revista Ceres, 63: 782-788, 2016.
GERUM, A. F. A. A. et al. Fruticultura Tropical: potenciais riscos e seus impactos. Cruz das Almas, BA: Embrapa Mandioca e Fruticultura, 2019. 28 p.
HAGHVERDI, A. et al. Perspectives on delineating management zones for variable rate irrigation. Computers and Electronics in Agriculture, 117: 154-167, 2015.
INMET. Ministério da Agricultura, Pecuária e Abastecimento. Instituto Nacional de Metereologia. Disponível em: <http://www.inmet.gov.br/portal/index.php?r=home2/index>. Acesso em: 15 jan. 2020.
» http://www.inmet.gov.br/portal/index.php?r=home2/index
LEITE, L. F. C. et al. Qualidade química do solo e dinâmica de carbono sob monocultivo e consórcio de macaúba e pastagem. Revista Brasileira de Engenharia Agrícola e Ambiental, 17: 1257-1263, 2013.
LIMA, F. V. et al. Variabilidade espacial de atributos físicos do solo em área de encosta sob processo de degradação. Revista Caatinga, 28: 53-63, 2015.
LUNDGREN, W. J. C.; SILVA, J. A. A.; FERREIRA, R. L. C. A Precisão da Estimativa do Erro da Krigagem pela Validação Cruzada. Floresta e Ambiente, 24: 124-114, 2017.
MATIAS, S. S. R. et al. Variabilidade espacial dos atributos do solo em duas áreas de manejo convencional no Cerrado piauiense. Revista de Ciências Agrárias, 58: 217-227, 2015.
MATIAS, S. S. R. et al. Recomendação de calagem com base na variabilidade espacial de atributos químicos do solo no Cerrado brasileiro. Revista de Ciências Agrárias, 42: 896-907, 2019.
NEGREIROS NETO, J. V. et al. Variabilidade espacial de atributos físico-químicos de um Latossolo Vermelho-Amarelo distrófico em sistema plantio direto. Semina: Ciências Agrárias, 35: 193-204, 2014.
PARIS, J. O. et al. Variability and spatial correlation of soil micronutrients and organic matter with macadamia nut production. Revista Brasileira de Engenharia Agrícola e Ambiental, 24: 31-36, 2020.
PEREIRA, V. G. M. F. et al. Irrigação e fertirrigação no desenvolvimento de eucalipto. Ciência Florestal, 29: 1100-1114, 2019.
RIBEIRO, A. C.; GUIMARÃES, P. T. G.; ALVAREZ, V. V. H. Recomendações para o uso de corretivos e fertilizantes em minas gerais: 5ª aproximação. Viçosa, MG: Comissão de Fertilidade do Solo do Estado de Minas Gerais, 1999, 359 p.
ROBERTSON, G. P. GS+ geostatistics for the environmental sciences: GS+ user's guide. Plainwell: Gamma Design Software, 2008, 152 p.
SANTOS, H. G. et al. Sistema Brasileiro de Classificação de Solos. 5. ed. Rio de Janeiro, RJ: Embrapa Solos, 2018. 356 p.
SIQUEIRA, G. M. et al. Estacionariedade do conteúdo de água de um Espodossolo Humilúvico. Revista Brasileira de Engenharia Agrícola e Ambiental, 19: 439-448, 2015.
VIAN, A. L. et al. Variabilidade espacial da produtividade de milho irrigado e sua correlação com variáveis explicativas de planta. Ciência Rural, 46: 464-471, 2016.
WERNER, E. T. et al. Coeficiente de variação como medida da precisão em experimentos de cultura de tecidos de plantas. Plant Cell Culture & Micropropagation, 8: 27-36, 2012.
YAO, R. J. et al. Determination of site-specific management zones using soil physico-chemical properties and crop yields in coastal reclaimed farmland. Geoderma, 232: 381-393, 2014.

Publication Dates

Publication in this collection
16 Apr 2021
Date of issue
Jan-Mar 2021

History

Received
17 Feb 2020
Accepted
26 Oct 2020

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] Paper extracted from the monography of the first author.

pH	TOC	P	K⁺	Ca²⁺	Mg²⁺	BS	CEC	V
H₂O	g kg^-1	mg dm^-3		------------ cmol_c dm^-3 -----------------				(%)
4.3	15.0	1.0	0.27	1.6	0.7	2.57	10.97	23.43
S	Na	B		Fe³⁺	Mn²⁺		Cu²⁺	Zn²⁺
mg dm^-3
14.2	2.5	0.2		44.0	0.5		2.0	1.0
Silt	Clay	Fine sand		Coarse sand	Gravel		Densities
Silt	Clay	Fine sand		Coarse sand	Gravel		Soil (Ds)	Particles (Dp)
	--------------- g kg^-1 --------------						g cm^-3
171	518	137		174	0.0		1.1	2.7

B	Cu²⁺	Mn²⁺	Zn²⁺	Dilution	Conductivity	Fertigation time	Lead time
-------------- kg --------------					dS m^-1	Min	Min
1.4	800	11.6	2.8	440/l	0.96	32	18

pH in H₂O	Very high acidity	High acidity	Medium	Weak	Alkaline
pH in H₂O	< 4.5	4.5 - 5.0	5.1 - 6.0	6.1 - 6.9	> 7.0
	Very low	Low	Medium	Good	Very good
K⁺ cmolc dm^-3	<0.50	0.5 - 1.0	1.0 - 2.0		> 2.00
P mg dm^-3	< 8.0	8.1 - 11.4	11.5 - 15.8	15.9 - 24.00	> 24.00
Ca²⁺ cmolc dm^-3	0.40	0.41 - 1.20	1.21 - 2.40	2.41 - 4.00	> 4.00
Mg²⁺ cmol_c dm^-3	0.15	0.16 - 0.45	0.46 - 0.90	0.91 - 1.50	> 1.50
H+Al cmolc dm^-3	1.00	1.01 - 2.50	2.51 - 5.00	5.01 - 9.00	> 9.00
BS cmol_c dm^-3	0.60	0.61 - 1.80	1.81 - 3.60	3.61 - 6.00	> 6.00
CEC cmol_c dm^-3	1.60	1.61 - 4.30	4.31 - 8.60	8.61 - 15.00	> 15.00
V %	20.0	20.1 - 40.0	40.1 - 60.0	-	-

Attribute	Depth (m)	Méd	Med	DP	Min.	MAx	Coefficients
Attribute	Depth (m)	Méd	Med	DP	Min.	MAx	Ass	Curt	CV (%)
PH	0-0.20	5.01	4.92	0.42	4.09	6.00	0.19	-0.58	8.53
H₂O	0.20-0.40	4.55	4.53	0.24	3.98	5.05	-0.36	0.33	5.30
TOC	0-0.20	0.98	1.03	0.37	0.12	1.58	-0.53	-0.45	38.21
g kg^-1	0.20-0.40	0.80	0.82	0.25	0.34	1.40	0.27	-0.04	31.73
P	0-0.20	53.86	52.22	23.21	16.98	185.21	0.77	0.65	43.09
mg dm^-3	0.20-0.40	13.57	16.75	5.78	2.74	19.37	-1.00	-0.77	42.64
K⁺	0-0.20	0.25	0.21	0.12	0.07	0.56	0.67	-0.20	50.43
cmol_c dm^-3	0.20-0.40	0.19	0.18	0.09	0.06	0.44	0.73	0.05	48.72
Ca²⁺	0-0.20	3.20	3.20	1.35	1.18	5.80	0.39	-1.01	42.17
cmol_c dm^-3	0.20-0.40	1.21	1.10	0.70	0.50	3.50	1.68	3.29	57.56
Mg²⁺	0-0.20	2.78	2.50	0.95	0.40	5.10	0.50	0.69	34.44
cmol_c dm^-3	0.20-0.40	0.72	0.50	0.45	0.00	1.90	0.75	-0.09	62.25
H + Al	0-0.20	7.36	7.50	1.85	4.29	10.56	-0.01	-1.25	25.13
cmol_c dm^-3	0.20-0.40	7.22	7.17	1.38	3.79	9.57	-0.22	-0.24	19.22
BS	0-0.20	6.18	6.35	1.75	2.34	10.38	0.12	-0.38	28.31
cmol_c dm^-3	0.20-0.40	2.03	1.97	0.72	1.06	4.15	1.23	1.73	11.65
CEC	0-0.20	15.50	16.00	4.48	4.74	25.26	-0.05	-0.38	28.90
cmol_c dm^-3	0.20-0.40	4.77	4.53	1.85	2.25	9.55	0.92	0.51	38.78
V%	0-0.20	39.75	39.55	0.93	38.20	41.69	0.39	-0.95	2.33
V%	0.20-0.40	42.39	42.05	2.68	39.09	49.70	1.17	1.16	6.32

Attribute	Depth (m)	Model	GDE (%)	Reach (m)	R²	CVRC
Attribute	Depth (m)	Model	GDE (%)	Reach (m)	R²	b	A
pH	0-0.20	gaussian	0.05	25.80	0.738	0.939	0.32
H₂O	0.20-0.40	gaussian	0.09	18.18	0.255	0.434	2.61
TOC	0-0.20	gaussian	38.54	31.17	0.794	0.858	0.14
g kg^-1	0.20-0.40	gaussian	14.81	32.77	0.818	1.00	0.00
P	0-0.20	gaussian	0.05	27.36	0.621	0.688	19.37
mg dm^-3	0.20-0.40	gaussian	0.24	38.45	0.968	0.897	1.17
K	0-0.20	spherical	23.20	70.40	0.916	0.965	0.01
cmol_c dm^-3	0.20-0.40	spherical	0.07	58.80	0.724	0.991	0.00
Ca	0-0.20	gaussian	0.04	27.19	0.848	0.967	0.16
cmol_cdm^-3	0.20-0.40	spherical	0.08	43.30	0.793	1.00	-0.01
Mg	0-0.20	spherical	7.88	57.80	0.855	0.650	1.01
cmol_cdm^-3	0.20-0.40	gaussian	0.22	23.20	0.533	0.048	0.80
H + Al	0-0.20	gaussian	30.52	94.05	0.849	0.941	0.43
cmol_cdm^-3	0.20-0.40	spherical	16.35	95.90	0.814	0.732	1.93
BS	0-0.20	exponential	0.03	70.80	0.824	0.860	0.90
cmol_cdm^-3	0.20-0.40	gaussian	46.57	45.55	0.772	0.822	0.39
CEC	0-0.20	gaussian	0.04	27.71	0.723	0.959	0.88
cmolcdm^-3	0.20-0.40	spherical	7.02	45.40	0.647	0.584	2.34
V%	0-0.20	spherical	6.87	17.33	0.720	0.619	15.21
V%	0.20-0.40	exponential	19.63	76.89	0.450	0.497	21.38

Brasil

Brasil

SPATIALITY OF SOIL CHEMICAL ATTRIBUTES IN A BANANA CULTIVATION AREA IN WEST BAHIA

ESPACIALIDADE DOS ATRIBUTOS QUÍMICOS DO SOLO EM ÁREA DE CULTIVO DE BANANEIRA NO OESTE DA BAHIA

ABSTRACT

RESUMO

INTRODUCTION

MATERIALS AND METHODS

RESULTS AND DISCUSSION

CONCLUSIONS

REFERENCES

Publication Dates

History