Published

2011-01-01

Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil

Authors

  • Alba Leonor Alba Leonor da Centro Nacional de Pesquisa de Solos - EMBRAPA/CNPS, Río de Janeiro-RJ, Brasil.
  • Emanoel G. de Moura Professor Doutor, Universidade Estadual del Maranhão, São Luis – MA, Brasil.
  • Jesús H. Camacho Tamayo Professor, Departamento de Engenharia Civil y Agrícola, Universidade Nacional da Colômbia, Bogotá.

The characterization of the soil spatial variability allows a better understanding of the relationships between the soil attributes and the environment. The objective of the study was to evaluate the spatial variability of corn production parameters and their relationship with soil chemical attributes. The study was carried out in the municipality of Miranda do Norte (MA, Brazil) in a Typic Plinthaquults. A mesh of 113 points was designed, taking samples at regular distances of 10 m, determining pH, organic material, P, K, Ca, Mg, and exchangeable acidity. The corn production parameters were ear weight, weight of 100 grains, and yield. The results were analyzed by means of descriptive statistics and geostatistical techniques. The pH and the weight of 100 grains were the only attributes with low variability. The sum of the bases did not show spatial dependence. The corn yield and the ear weight showed similar high correlation and spatial dependence. The production parameters showed a significant influence of the soil chemical attributes, principally those that define the acidity and the cations presence. The contour maps allowed the identification of the soil spatial attributes and their relationship to corn yield.

 

Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil

 

Evaluación de parámetros productivos de maíz y su relación espacial con atributos químicos del suelo

 

Alba Leonor da S. Martins1, Emanoel G. de Moura2, and Jesús H. Camacho-Tamayo

1 Centro Nacional de Pesquisa de Solos - EMBRAPA/CNPS, Río de Janeiro-RJ, Brasil.
2 Professor Doutor, Universidade Estadual del Maranhã, Sã Luis - MA, Brasil.
3 Professor, Departamento de Engenharia Civil y Agrícola, Universidade Nacional da Colômbia, Bogotá.
4 Corresponding author: jhcamachot@unal.edu.co

Received for publication: 6 November, 2009. Accepted for publication: 2 February, 2011.


ABSTRACT

The characterization of the soil spatial variability allows a better understanding of the relationships between the soil attributes and the environment. The objective of the study was to evaluate the spatial variability of corn production parameters and their relationship with soil chemical attributes. The study was carried out in the municipality of Miranda do Norte (MA, Brazil) in a Typic Plinthaquults. A mesh of 113 points was designed, taking samples at regular distances of 10 m, determining pH, organic material, P, K, Ca, Mg, and exchangeable acidity. The corn production parameters were ear weight, weight of 100 grains, and yield. The results were analyzed by means of descriptive statistics and geostatistical techniques. The pH and the weight of 100 grains were the only attributes with low variability. The sum of the bases did not show spatial dependence. The corn yield and the ear weight showed similar high correlation and spatial dependence. The production parameters showed a significant influence of the soil chemical attributes, principally those that define the acidity and the cations presence. The contour maps allowed the identification of the soil spatial attributes and their relationship to corn yield.

Key words: precision agriculture, spatial structure, Zea mays


RESUMEN

La caracterización de la variabilidad espacial del suelo permite una mejor comprensión de las relaciones entre las características del suelo y el ambiente. El objetivo del trabajo fue evaluar la variabilidad espacial de parámetros productivos del maíz y su relación con atributos químicos del suelo. El estudio se realizó en el municipio de Miranda do Norte (MA-Brasil) en un Typic Plinthaquults. Se diseñó una malla de 113 puntos, tomando muestras cada 10 m y determinando pH, materia orgánica, P, K, Ca, Mg y Ac.I. Los parámetros productivos del maíz fueron peso de la espiga, peso de 100 granos y productividad. Los resultados fueron analizados mediante estadística descriptiva y técnicas de geoestadística. El pH y el peso de 100 granos fueron los únicos atributos con baja variabilidad. La suma de bases no presentó dependencia espacial. La producción de maíz y el peso de la espiga presentaron alta correlación y dependencia espacial similares. Los parámetros productivos presentaron influencia significativa de los atributos químicos del suelo, principalmente aquellos que definen la acidez y la presencia de cationes. Los mapas de contorno permitieron verificar la distribución espacial de los atributos del suelo y su relación con la productividad de maíz.

Palabras clave: agricultura de precisión, estructura espacial, Zea mays L., semivariograma, kriging.


Introduction

Farmers have observed variations in the soil across the centuries that are attributes of the management of their crops; nevertheless, their areas under cultivation are managed as if they were uniform. During the last few decades, with the realization that these areas are not uniform, these variations in the soil are taken into consideration, changing the management for each one of them and adopting modern technologies to increase the crops productivity and optimize the use of fertilizers and other external inputs. These changes have led to a search for new alternative technologies and new concepts for the management of the productive process, due to large amounts of information, which vary in space and time.

The soil variability occurs due to factors that act at different spatial and temporal scales, produced by natural, complex pedagogical processes (relief and moisture regimes) or induced by human actions (Molin et al., 2008), as happens in the crops production, which modify the variability of thea soil (Burgos et al., 2006), especially in tasks such as tilling and fertilization, principally on the surface (Camacho-Tamayo et al., 2008).

The characterization of the spatial variability of the soil allows a better understanding of the complex relationships between the soil attributes and the environment (Goovaerts, 1998), helping decision-making for the adequate soil use and crops production (Bouma et al., 1999). Interest in information relevant to the soil spatial attributes has increased, resulting in the development of models and management systems (Godwin and Miller, 2003). However, site specific management of the soil by can be unviable if the cost of the required analyses is high (Bongiovanni and Lowenberg-Deboer, 2000). Determining the variability of the soil attributes by means of appropriate sampling and processing of the results using tools such as geostatistics can establish optimum distances and the dependence between two or more variables can lead to a reduction of the sampling costs. Geostatistics is a tool that is adequate for understanding the variation of the soil attributes, and can be used at different scales on the basis of precise initial data, depending on the desired resolution of the study (Webster, 2008).

Šamonil et al. (2010) affirm that there exists a heterogeneity of the attributes in different types of soils, and that the spatial dependence is influenced by the relief, which leads to establishing areas of management differentiated on the basis of each attribute analyzed, and also indicates the necessity of carrying out studies of the different classes of soil.

This study had the aim of evaluating the spatial variability of some corn production parameters and their relationship with the chemical attributes, in a Typic Plinthaquults, by means of statistical and geostatistical techniques.

 

Materials and methods

Area of study

The study was carried out in the municipality of Miranda do Norte (MA, Brazil), in 1 ha cultivated with corn (Zea mays L.) under an agroforestry system, a zone where family agriculture predominates, located at 3° 36' 47" south latitude, 44° 34' 30" west longitude and 53 m.a.s.l. The soil is a Typic Plinthaquults, with medium texture and flat relief. According to Köppen classification, the region is Aw'- tropical humid climate, with an average temperature of 27°C and precipitation between 1600 and 2000 mm annually, concentrated in the months of December and June, a dry climate predominating in other months.

Sampling and laboratory analysis

For the sampling, a mesh of 113 points was designed, regularly distanced each 10 m. At each point, soil samples were taken at a depth of 0 - 0.20 mm, which were air dried until they reached an equilibrium point and later were passed through a sieve of 2 mm, for the performance of the analysis, obtaining pH (CaCl2 0.01M), available P content (resin), organic matter (OM), K, Ca, Mg and exchangeable acidity Ac.E, according to the methodology proposed by Raij et al. (2001). On the basis of these results the cation exchange capacity (CEC) was calculated, the sum of the bases (SB) and base saturation (V%) of the soil. Corn productivity was evaluated by collecting ears in an area of 8 m2 at intervals of 10 x 10 m, in order to estimate the average ear weight (Ew), crop yield (Cy) and weight of 100 grains (Gw).

Processing and data analysis

Initially an exploratory study of data was carried out, calculating average, median, minimum and maximum, coefficient of variation (CV), skewness and kurtosis. Additionally the Kolmogorov-Smirnov test was carried out in order to evaluate the normality. All of the statistical analyses were processed using the software SPSS™ 17.0. For the analysis of the CV, the Warrick and Nielsen classification (1980) was considered, with low variability for values lower than 12%, medium between 12 and 60%, and high for values greater than 60%.

For the fit of the experimental data to the theoretical semivariogram models, the regionalized variable theory was considered, which uses different methods of analysis of spatial variation, one of them being the semivariogram (Webster and Oliver, 2007). On the basis of the fit to these models, the nugget (C0), sill (Co+C) and range (A) were determined, besides the Degree of Spatial Dependence (DSD) as the ratio between the nugget and the sill (C/Co+C), being considered strong for DSD above 0.75, moderate for DSD between 0.25 and 0.75 and weak for DSD below 0.25 (Cambardella et al., 1994). The semivariograms were calculated using the program GS+. For the selection of the theoretical semivariogram models, the least sum of squared residuals (SSR), the coefficient of determination (R2) of the equation of fit and similar values obtained between the real and the estimated value were considered, which are obtained in the crossed validation, appropriate indicators for such purpose (Faraco et al., 2008; Johann et al., 2010).

On the basis of the semivariogram models of the attributes that expressed spatial dependence, interpolation by ordinary kriging was carried out, which is considered the best unbiased linear estimator and that of least variance (Diggle and Ribeiro, 2000), for making a prediction at non-sampled sites, the results being shown by means of contour maps. This procedure was performed using the program Surfer v.9 (Golden Software Inc., 2008).

 

Results and discussion

Statistical analysis

According to the Kolmogorov-Smirnov test, not all the attributes approach normal distribution (Tab. 1), in that the P, pH, cation exchange capacity (CEC) and base saturation (V) showed great differences between the mean and the median and high values of skewness in relation to the other attributes analyzed. A similar situation was observed for the production values of the ear weight (Ew) and crop yield (Cy). According to Cressie (1993), more than normality it is convenient to verify that the distribution does not show long tails, in order not to compromise the results, especially when kriging is carried out, where the estimations are based on mean values (Warrick and Nielsen, 1980). Another important fact is the occurrence of the proportional effect between the mean and the data variance, along a surface, which permits estimating defined sills in the theoretical semivariogram models.

For the other attributes and Gw, the values found for the mean and the median are similar, indicating symmetric distributions, which are verified by the values close to zero for skewness and kurtosis, approaching normal distribution, which is confirmed by the normality test.

Crop yield and Ew showed medium variability. In the case of these parameters, it is convenient to consider that their behavior depends not only on the edaphic conditions and that their variability can be affected by environmental conditions (i.e. wind and relative humidity) which influence the process of pollination (Ortega and Santibañez, 2007).

According to the coefficient of variation (CV), the pH and Gw showed low variability. This characteristic of low variability of the pH is reported by several authors in different soil classes (Camacho-Tamayo et al., 2008; Cruz et al., 2011). The other attributes showed medium variability, highlighting the fact that the P and the K were the attributes with the greatest variability (CV of 45.90% and 38.80% respectively), explained by the incorporation of these elements in agricultural production (Camacho-Tamayo et al., 2008).

Geostatistical analysis

The sum of the bases was the only attribute that did not show a fit to the theoretical semivariogram models, indicating that their behavior in the soil is random, showing a seed effect (Tab. 2). The attributes fit different models, with a predominance of spherical and exponential models.

Because of the values obtained for the coefficient of determination (R2) and the crossed validation coefficient (CVC), it can be seen that the fit to the models was adequate, with values close to one in the majority of the attributes analyzed, as is also reported by Silva et al. (2003), in that Ca and Mg exhibited the lowest values of R2, possibly influenced by the anthropic management, occasioned by the surface distribution of amendments, a practice that is carried out in this zone with frequency in corn cultivation, which modifies the natural distribution of the attributes (Camacho-Tamayo et al., 2008).

The greatest ranges were observed for pH, Ac.E, CEC and V, attributes that are strongly correlated. Of the production parameters, Ew and Cy showed similar ranges, and a strong correlation can be seen between them, indicating that the greater the ear weight the greater the productivity.

No attribute or production parameter showed weak DSD. The variables that fit to spherical models showed moderate DSD. The attributes pH, Ca and Ac.E, as well as Cy, showed strong DSD. A moderate DSD of pH, P, K and Mg is also reported for Oxisols (Camacho-Tamayo et al., 2008), indicating that it is a common characteristic in soils undergoing crop production.

Lineal correlation and kriging

The correlation analysis revealed that of the greatest coefficients found among the attributes (Tab. 3), those that explain the linear relationship of the soil acidity (pH and Ac.I) to the contents of Ca and Mg stand out, and as a consequence the sum of bases, cation exchange capacity (CEC) and base saturation (V). This behavior is confirmed in the contour maps, where areas of high values of pH (Fig. 1D) showed the greatest values of V (Fig. 1E) and the least values of Ac.E. The OM also showed a significant correlation with V, which is reasonably verified in the contour maps (Figs. 1E and 1F).

According to Canellas et al. (2000), the OM directly influences the behavior of V and CEC. Another important fact is the strong influence of the Ac.E on CEC, attributes that showed high positive correlation and that can be seen in the maps (Figs. 2E and 2F) and in the semivariograms obtained for these attributes, which fit the same model (Tab. 2), with similar range. This behavior is also reported by Salviano et al. (1998) and is explained by the greater presence of this cation in the soil, with respect to the others used in the calculation of the CEC (Tab. 1).

For the production parameters, it can be seen that only Gw showed a significant correlation with the content of K, indicating that K directly influences Gw. This significant correlation is reflected in the contour maps, where areas with greater grain weight correspond to areas of greater K content (Figs. 1A and 2B), being divergent at the bottom right of the maps.

Corn productivity is strongly affected by Ew, as is proven in the significant correlation and the resemblance of the contour maps between these parameters (Figs. 1B and 1C). The influence of the OM on the formation of the ears and corn yield is also verified, parameters that showed a positive correlation. The attributes related to the soil acidity also influenced Cy and the ears formation.

The low relationship between production and the P and K contents is also reported by other authors (Santos et al., 2001), but does not correspond to the majority of the studies of fertility, which show a direct relationship between these attributes and grain production. A possible explanation for these results is the high rate of fertilization with nutrients applied homogeneously by the farmers of the zone, which can hide the effects of the inherent fertility of the soil. Another explanation could be that the level of fertility of the soil at the time of the study was not a limiting factor for yield, and that possibly there are other determining attributes of the soil for crop production, such as the physical attributes or the presence of microorganisms (Ortega and Santibáñez, 2007).

 

Conclusions

The attributes showed low or medium variability, the cation exchange capacity (CEC) being the only attribute that did not show spatial dependence. The other attributes showed spatial dependence, fitting semivariogram models, with a strong or moderate degree of dependence.

The production parameters showed defined variability and spatial dependence. Corn productivity and ear weight are highly correlated attributes, with a similar behavior relative to variability and spatial dependence.

The use of different statistical tools helped to identify the spatial variability of the soil, as well as an understanding and establishment of the various relationships between the attributes that characterize the soil, techniques that can support decision making, for a better administration and control of agricultural production.

 

Literature cited

Bongiovanni, R. y J. Lowenberg-Deboer. 2000. Nitrogen management in corn using site-specific crop response estimates from a spatial regression model. In Robert, P.C., R.H. Rust y W.E.Larson (Eds.). Proceedings of the Fifth International Conference on Precision Agriculture. ASA/CSSA/SSSA, St. Paul, Minnesota, USA.

Bouma, J., J. Stoorvogel, B.J. Van Alphen y H.W.G.Booltink. 1999. Pedology, precision agriculture, and the changing paradigm of agricultural research. Soil Sci. Soc. Am. J. 63(6), 1763-1768.

Burgos, P., E. Madejón, A. Pérez-de-Mora y F. Cabrera. 2006. Spatial variability of the chemical characteristics of a trace-elementcontaminated soil before and after remediation. Geoderma 130(1-2), 157-175.

Camacho-Tamayo, J.H, C.A. Luengas y F.R. Leiva. 2008. Effect of agricultural intervention on the spatial variability of some soils chemical properties in the eastern plains of Colombia. Chilean J. Agric. Res. 68(1), 42-55.

Cambardella, C.A., T.B. Moorman, J.M. Novak, T.B. Parkin, D.L. Karlen, R.F. Turco y A.E. Konopka. 1994. Field-scale variability of soil properties in Central Iowa Soils. Soil Sci. Soc. Am. J. 58(5), 1501-1511.

Cressie, N. 1993. Statistics for spatial data. John Wiley and Sons, New York. 928 p.

Cruz, J.S., R.N. de Assis Júnior, S.S.R. Matias y J.H. Camacho- Tamayo. 2011. Spatial variability of an Alfisol cultivated with sugarcane. Cien. Inv. Agr. 38(1), 155-164

Diggle, P.J. y J.R. Ribeiro,. 2000. Model Based Geostatistics. 1ed. São Paulo: Associação Brasileira de Estatística. 129 p.

Faraco, M.A., M.A. Uribe-Opazo, E.A. Silva, J.A. Johann y N.N. Borssoi. 2008. Seleção de modelos de variabilidade espacial para elaboração de mapas temáticos de atributos físicos do solo e produtividade da soja. Rev. Bras. Ciênc. Solo 32(2), 463-476.

Godwin, R.J. and P.C.H. Miller. 2003. A review of the technologies for mapping within-field variability. Biosyst. Eng. 84(4), 393-407.

Golden Software Inc. (2008). Surfer v.9, Golden, CO

Goovaerts, P. 1998. Geostatistical tools for characterizing the spatial variability of microbiological and physico-chemical soil properties. Biol. Fertil. Soils 27(4), 315-334.

Johann, J.A., M.C.A. Silva, M.A. Uribe-Opazo and G.H. Dalposso. 2010. Variabilidade Espacial da rentabilidade, perdas na colheita e produtividade do Feijoeiro. Eng. Agríc. 30(4), 700-714.

Molin, J.P., F.R. Leiva and J.H. Camacho-Tamayo. 2008. Tecnología de la agricultura de precisión en el contexto de la sostenibilidad. En: Leiva, F.R. (Ed.). Agricultura de precisión en cultivos transitorios. Bogotá, Universidad Nacional de Colombia. pp. 13-41.

Ortega, R.A. and O.A. Santibáñez. 2007. Determination of management zones in corn (Zea mays L.) based on soil fertility. Comput. Electron. Agric. 58(1), 49-59.

Raij, van B., J.C. Andrade, H. Cantarella and J.A. Quaggio. 2001. Análise química para avaliação da fertilidade de solos tropicais. Campinas: Instituto Agronômico. 285 p.

Šamonil, P., K. Král and L. Hort. 2010. The role of tree uprooting in soil formation: A critical literature review. Geoderma 157(3-4), 65-79.

Salviano, A.A.C., S.R. Vieira and G. Sparovek. 1998. Variabilidade espacial de atributos de solo y de Crotalaria juncea L em área severamente erodida. R. Bras. Ci. Solo 22(1), 115-122.

Santos, A.O., J.V.G. Maziero, A.C. Cavalli, M.M. Valeriano, H. Oliveira, J.F.L. Moraes and K. Yanai. 2001. Monitoramento localizado da produtividade de milho cultivado sob irrigação. Rev. Bras. Eng. Agríc. Ambient. 5(1), 88-95.

Silva, V.R., J.M. Reichert, L. Storck and S. Feijó, S. 2003. Variabilidade espacial das características químicas do solo e produtividade de milho em um argissolo vermelho-amarelo distrófico arênico. R. Bras. Ci. Solo 27(6), 1013-1020.

Warrick, A.W. and D.R. Nielsen. 1980. Spatial variability of soil physical properties in the field. In: Hillel, D. (ed.) Applications of soil physics. New York: Academic Press. p. 319-344.

Webster, R., and Oliver, M.A. 2007. Geostatistics for environmental scientists. John Wiley & Sons Inc., Hoboken, NJ.

Webster, R. 2008. Soil science and geostatistics. In: Krasilnikov, P., F. Carré y L. Montanarella (eds.). Soil geography and geostatistics - concepts and applications. European Commission, Joint Research Centre, Institute for Environment and Sustainability, p. 1-11.

How to Cite

APA

Alba Leonor da, A. L., de Moura, E. G. and Camacho Tamayo, J. H. (2011). Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil. Agronomía Colombiana, 29(1), 99–106. https://revistas.unal.edu.co/index.php/agrocol/article/view/28640

ACM

[1]
Alba Leonor da, A.L., de Moura, E.G. and Camacho Tamayo, J.H. 2011. Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil. Agronomía Colombiana. 29, 1 (Jan. 2011), 99–106.

ACS

(1)
Alba Leonor da, A. L.; de Moura, E. G.; Camacho Tamayo, J. H. Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil. Agron. Colomb. 2011, 29, 99-106.

ABNT

ALBA LEONOR DA, A. L.; DE MOURA, E. G.; CAMACHO TAMAYO, J. H. Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil. Agronomía Colombiana, [S. l.], v. 29, n. 1, p. 99–106, 2011. Disponível em: https://revistas.unal.edu.co/index.php/agrocol/article/view/28640. Acesso em: 29 mar. 2024.

Chicago

Alba Leonor da, Alba Leonor, Emanoel G. de Moura, and Jesús H. Camacho Tamayo. 2011. “Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil”. Agronomía Colombiana 29 (1):99-106. https://revistas.unal.edu.co/index.php/agrocol/article/view/28640.

Harvard

Alba Leonor da, A. L., de Moura, E. G. and Camacho Tamayo, J. H. (2011) “Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil”, Agronomía Colombiana, 29(1), pp. 99–106. Available at: https://revistas.unal.edu.co/index.php/agrocol/article/view/28640 (Accessed: 29 March 2024).

IEEE

[1]
A. L. Alba Leonor da, E. G. de Moura, and J. H. Camacho Tamayo, “Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil”, Agron. Colomb., vol. 29, no. 1, pp. 99–106, Jan. 2011.

MLA

Alba Leonor da, A. L., E. G. de Moura, and J. H. Camacho Tamayo. “Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil”. Agronomía Colombiana, vol. 29, no. 1, Jan. 2011, pp. 99-106, https://revistas.unal.edu.co/index.php/agrocol/article/view/28640.

Turabian

Alba Leonor da, Alba Leonor, Emanoel G. de Moura, and Jesús H. Camacho Tamayo. “Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil”. Agronomía Colombiana 29, no. 1 (January 1, 2011): 99–106. Accessed March 29, 2024. https://revistas.unal.edu.co/index.php/agrocol/article/view/28640.

Vancouver

1.
Alba Leonor da AL, de Moura EG, Camacho Tamayo JH. Evaluation of corn production parameters and their spatial relationship with chemical attributes of the soil. Agron. Colomb. [Internet]. 2011 Jan. 1 [cited 2024 Mar. 29];29(1):99-106. Available from: https://revistas.unal.edu.co/index.php/agrocol/article/view/28640

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