Use and abuse of fertigation. Modification of the soil in greenhouses in small-scale agriculture

Huerta-Naveda, Diego; Galvis-Spinola, Arturo; Hernández-Mendoza, Teresa Marcela; Delgadillo-Martínez, Julián; Huerta-Naveda, Diego; Galvis-Spinola, Arturo; Hernández-Mendoza, Teresa Marcela; Delgadillo-Martínez, Julián

doi:10.29312/remexca.v14i6.3112

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Revista mexicana de ciencias agrícolas

versión impresa ISSN 2007-0934

Rev. Mex. Cienc. Agríc vol.14 no.6 Texcoco ago./sep. 2023 Epub 30-Oct-2023

https://doi.org/10.29312/remexca.v14i6.3112

Articles

Use and abuse of fertigation. Modification of the soil in greenhouses in small-scale agriculture

Diego Huerta-Naveda¹

Arturo Galvis-Spinola¹^§

Teresa Marcela Hernández-Mendoza²

Julián Delgadillo-Martínez¹

^¹Edafología-Campus Montecillo-Colegio de Postgraduados. Carretera México-Texcoco km 36.5, Montecillo, Texcoco, Estado de México. CP. 56264.

^²Departamento de Irrigación-Universidad Autónoma Chapingo. Carretera México-Texcoco km 38.5, Chapingo, Texcoco, Estado de México. CP. 56230.

Abstract

Protected agriculture helps improve agricultural productivity, but if the management is not adequate, it will increase the risk of affecting the environment and the profitability of crops. Therefore, in the municipality of Tetela de Ocampo, Puebla, in 2021, the chemical environment of the soil in greenhouses in the region that use fertigation was evaluated. To identify the details of agricultural activities, a questionnaire prepared specifically was applied to cooperating farmers, collecting a composite soil sample (five subsamples) per unit of production evaluated and uncultivated lands were included as a reference of the initial condition. The analysis of the samples was based on the NOM-021-RECNAT-2000 (NOM). The average annual yield of tomato is 31 ±7.6 kg m^-2 and 87% of greenhouses have an area of less than 3 000 m². They have technical assistance provided by companies and individuals, which include training courses and periodic soil analysis. In this study, excessive levels of all the chemical indicators established in the NOM were detected in the soil; nevertheless, the same fertilization program that has been carried out for several years in the region continues.

Keywords: edaphic chemical environment; fertilizers; productivity; tomato

Resumen

La agricultura protegida coadyuva a mejorar la productividad agrícola, pero si el manejo no es el adecuado, incrementará el riesgo de afectar al ambiente y la rentabilidad de los cultivos. Por lo anterior, en el municipio de Tetela de Ocampo, Puebla, durante 2021 se evaluó el ambiente químico del suelo en invernaderos de la región que emplean el fertirriego. Para identificar los pormenores de las actividades agrícolas, se aplicó un cuestionario elaborado ex profeso a agricultores cooperantes, colectando una muestra de suelo compuesta (cinco submuestras) por unidad de producción evaluada y se incluyeron terrenos sin cultivar como referencia de la condición inicial. El análisis de las muestras se basó en la NOM-021-RECNAT-2000 (NOM). El rendimiento promedio anual de jitomate es de 31 ±7.6 kg m^-2 y 87% de los invernaderos tienen una superficie inferior a 3 000 m². Cuentan con asistencia técnica provista por empresas y particulares, que incluyen cursos de capacitación y análisis periódico del suelo. En este estudio se detectaron en el suelo niveles excesivos de todos los indicadores químicos establecidos en la NOM; sin embargo, continúa el mismo programa de fertilización que se realiza desde hace varios años en la región.

Palabras clave: ambiente químico edáfico; fertilizantes; jitomate; productividad

Greenhouse horticultural production is a technological alternative that can be successful even in small production units if properly conducted. For example, through fertigation it is possible to optimize the application of nutrients, but the excess increases the concentration of salts in the soil (^{Zörb et al., 2019}) and affects the environment (^{Yasuor et al., 2020}). Therefore, the objective of this work was to evaluate the effect of fertigation on soil fertility and tomato productivity under greenhouse in the small-scale agriculture in the municipality of Tetela de Ocampo, Puebla.

In the study area, the family is the central productive structure and due to its greater profitability, it has been engaged in protected agriculture for 16 years, replacing that of the extensive type. The region is humid temperate with rainfall of 600 to 1 600 mm per year, average annual temperature of 12 °C to 18 °C and Luvisol soils, which occupy 81% of the land of the region (^{INEGI, 2009}). These soils are used to build the planting beds of each greenhouse.

The evaluation of the effect of fertigation management on soil fertility and tomato productivity was carried out based on the methodology proposed by ^{Hernández-Mendoza and Galvis-Spinola (2017}), that is: 1) tour the area to detect environmental conditions; 2) based on a survey, identify the problems of the region, applying to each farmer a questionnaire prepared specifically; 3) diagnose the current condition of the soil based on its analysis in the laboratory; and 4) relate agricultural management practices to regional information and soil evaluation. In this case, a sample of 30 farmers was used (Figure 1), equivalent to 10% of the total (95% confidence and 1% margin of error).

Figure 1 Location of greenhouses owned by cooperating farmers in the municipality of Tetela de Ocampo, Puebla. Satellite image taken from Google Earth Version 9.155.0.2.

The questionnaire consisted of 36 closed-ended and multiple-choice questions, which allowed knowing the area of each greenhouse, years of use, yield and quality of the crop, seasons per year, training, technical advice, non-nutritional disorders, inputs used, doses and times of application, irrigation management, use and frequency of soil analysis, correction of problems and management of amendments.

Soil sampling was done based on the ^{NOM
(2002)}, and in each greenhouse five subsamples were collected at 0-20 cm depth to form a composite sample, taken in the middle of the planting bed, and avoiding the drip line. Uncultivated lands were included as a reference of the original condition. The analyses were carried out in the laboratories of the Colegio de Postgraduados, Montecillo Campus, following the ^{NOM (2002)}. The following were determined: pH, organic matter, inorganic nitrogen, electrical conductivity, nitrate, ammonium, texture, phosphorus, potassium, exchangeable bases and their respective soluble forms.

Information from the survey and laboratory analyses was evaluated based on the descriptive statistics mean and standard deviation, frequency distribution, correlation and simple regression. The area of the greenhouses varies from 1 000 to 11 000 m² (87% of them less than 3 000 m²) with a maximum of 16 years of use. Of the producers, 27% have been engaged ≤ 4 years in protected agriculture and 40% > 8 years. Eighty-seven percent hire technical advice from companies (17%) or independent agronomists (70%), 53% receive training and do periodic analysis of their soils; however, technical decisions fall on advisors, because 63% of farmers admit to not knowing the inputs applied in their greenhouse.

The tomato is grown in two cycles per year, with average annual yield of 31 ±7.6 kg m^-2. In 63%, productivity fluctuates from 14 to 16 kg m^-2 per cycle, which they attribute to some limiting factor that they have not yet identified, which is why in 90% of the units, amendments are applied as preventive measures to reverse this situation, even without knowing what they are trying to solve.

In 80% of the soils, the clayey fraction predominates. The native pH is 6.1 and coincides with 13% of greenhouses, because in 47% it is lower (pH from 4.2 to 5.9) and in 40% higher (pH from 6.3 to 7.8). This would be explained by what was reported by ^{Barak et al. (1997}), who assert that chemical disturbance is associated with the intensity, frequency and type of fertilizers used. There is 1.3% organic matter in uncultivated lands and in 87% of greenhouses it ranges from 2 to 6.5%, which is consistent with the continuous use of organic inputs in the area, which coincides with ^{Mundo-Coxca et al. (2020}) for the same region.

The electrical conductivity (C_E) in areas without agricultural activity is 0.2 dS m^-1, while in 53% of cultivated areas it varies from 0.5 to 2.5 dS m^-1 and in 47% it was higher than 3 dS m^-1, which, according to ^{Sánchez-González et
al. (2014}), would already affect tomato productivity. Figure 2 shows the trend between C_E and base cations in their exchangeable and soluble forms.

Figure 2 Trend of electrical conductivity (C_E) with the sum of the base cations in their exchangeable (S_CI) and soluble (S_CS) forms, of the soils of greenhouses of Tetela de Ocampo, Puebla.

C_E is closely associated with ionic species in the soil solution, but not with exchangeable ones, a situation similar to that observed by ^{Coitiño-López et al. (2015}), who used these comparisons to characterize agroecological resources. In Table 1, C_E was correlated with the different ionic species to elucidate what influence they have on the use of inputs in the region.

Table 1 Significant Pearson correlation coefficients (p< 0.05) between electrical conductivity (C_E) and ionic species analyzed in soils in greenhouses of Tetela de Ocampo, Puebla

^*Ca_E

Mg_E

K_E

Na_E

Ca_S

Mg_S

K_S

Na_S

^**Ni

NO₃

NH₄

C_E

-0.51

0.82

0.9

0.88

0.5

0.91

0.94

0.96

^*= base cations, cMol kg^-1 (E= exchangeable; S= soluble). ^**= in mg kg^-1; Ni= inorganic nitrogen; NO₃= nitrate; NH₄= ammonium; P= phosphorus (P); ns= not significant.

Phosphorus did not modify the concentration of salts in the soil solution, which is explained by the reaction between its ionic forms and the edaphic solid phase, which restrict its mobility and concentration in the aqueous medium (^{Barrow, 1978}). In all cases, the ‘high’ limit of the base cations of the NOM (2002) was exceeded, which is attributed to the clayey nature of the soils. The correlation was significant (p> 0.05) between exchangeable and soluble species for potassium (r= 0.9) and sodium (r= 0.92).

The nutrients are applied daily through irrigation tape with chemical fertilizers plus organic inputs in 10% of cases. The following predominate: calcium nitrate (27%), potassium sulfate (17%), potassium nitrate (14%) and magnesium sulfate (13%) in average doses of 0.79, 0.51, 0.41 and 0.39 kg m^-2, respectively. The highest rate is 1.14 kg m^-2 d^-1 during the period of cuts of marketable fruits. Fertilizer injection is 9 kg m^-2 per cycle and fluctuates from ≤ 8 kg m^-2 in 63% of greenhouses to ≥ 20 kg m^-2 in 23% of them. Figure 3 shows the annual production of tomato and the dose of nitrogen, phosphorus and potassium applied per year, in each greenhouse evaluated in the study area.

Figure 3 Annual production of tomato and doses of nitrogen (a), phosphorus (b) and potassium (c) applied per year, in each greenhouse evaluated in Tetela de Ocampo, Puebla

Inorganic soil nitrogen was <10 mg kg^-1 in 57% of cases, which may be due to its mobility and transformation in the soil (^{Cameron et al., 2013}). In greenhouses where soil samples are collected for periodic chemical analysis, excess calcium and magnesium are reported on a recurring basis. Despite this, calcium nitrate and magnesium sulfate are the preferred sources for farmers. Something similar happens for phosphorus and potassium, because they continue to be applied on a daily basis without favorable effect between the yield of the tomato and the amount of nutrients added.

The annual yield fluctuated between 14 and 44 kg m^-2, in 30% of the greenhouses ≤24 kg m^-2 is obtained, in 53% 33 kg m^-2 and in 17% >40 kg m^-2. According to the federal government (^{SIAP, 2021}), the region would rank 6th nationally in productivity. In this regard, according to the results shown in the figure under discussion, fertilization does not explain the variation in the amount of product harvested. Something similar to this situation occurred in China (^{Ju et al., 2011}), which is why those authors evaluated the efficiency of nitrogen use in greenhouse tomatoes, in which 18% of what was applied was recovered and the rest was leached, which would explain why the crop yield was not affected.

In this study, phosphorus fluctuated from 47 to 560 mg kg^-1 and potassium from 429 to 2 291 mg kg^-1 as a result of their continuous application and because the ionic forms of phosphorus (^{Barrow,
1978}) and potassium (^{Griffioen,
2001}) participate in reactions that promote their accumulation in the edaphic medium. Both cases exceed the highest levels of the ^{NOM (2002)}, which is 11 mg kg^-1 for phosphorus and 235 mg kg^-1 for potassium.

Conclusions

The methodology used in the present study allowed detecting and characterizing the agricultural management that is carried out in the greenhouses in the small-scale agriculture of the municipality of Tetela de Ocampo, Puebla. The area of each production unit is less than 3 000 m² in 87% of the greenhouses studied, they have advice, periodic soil analysis and training for producers. The intensive use of inputs increased edaphic organic matter and favored the accumulation of soil nutrients, exceeding what is established in Mexican regulations (^{NOM, 2002}). The average annual productivity of tomato remains unchanged at 31 kg m^-2, the same happens with the programming and use of fertilizers.

Bibliografía

Barak, P.; Jobe, B. O.; Krueger, A. R.; Peterson, L. A. and Laird, D. A. 1997. Effects of long-term soil acidification due to nitrogen fertilizer inputs in Wisconsin. Plant Soil. 197(1):61-69. https://www.jstor.org/stable/42948199. [ Links ]

Barrow, N. J. 1978. The description of phosphate adsorption curves. J. Soil Sci. 29(4):447-462. https://doi.org/10.1111/j.1365-2389.1978.tb00794.x. [ Links ]

Cameron, K. C.; Di, H. J. and Moir, J. L. 2013. Nitrogen losses from the soil/plant system: a review. Ann. Appl. Biol. 162(2):145-173. https://doi.org/10.1111/aab.12014. [ Links ]

Coitiño-López, J.; Barbazán, M. y Ernst, O. 2015. Conductividad eléctrica aparente para delimitar zonas de manejo en un suelo agrícola con reducida variabilidad en propiedades fisicoquímicas. Agrociencia Uruguay. 19(1):102-111. http://www.scielo.edu.uy/scielo.php?script=sci_arttext&pid=S230115482015000100012&lng=es&tlng=pt. [ Links ]

Griffioen, J. 2001. Potassium adsorption ratios as an indicator for the fate of agricultural potassium in groundwater. J. Hydrol. 254(1-4):244-254. https://doi.org/10.1016/S0022-1694(01)00503-0. [ Links ]

Hernández-Mendoza, T. M. y Galvis-Spinola, A. 2017. Productividad de la caña de azúcar por régimen hídrico y uso de fertilizantes en suelos someros. Interciencia. 42(4):218-223. https://www.interciencia.net/wp-content/uploads/2017/08/218-5856-hernandez-42-4.pdf. [ Links ]

INEGI. 2009. Instituto Nacional de Estadística y Geografía. Prontuario de información geográfica nacional. https://www.inegi.org.mx/contenidos/app/mexicocifras/datos-geograficos/21/21172.pdf. [ Links ]

Ju, M.; Xu, Z.; Wei-Ming, S.; Guang-Xi, X. and Zhao-Liang, Z. 2011. Nitrogen balance and loss in a greenhouse vegetable system in southeastern China. Pedosphere. 21(4):464-472. https://doi.org/10.1016/S1002-0160(11)60148-3. [ Links ]

Mundo-Coxca, M.; Jaramillo-Villanueva, J. L.; Morales-Jiménez, J.; Macías-López, A. y Ocampo-Mendoza, J. 2020. Caracterización tecnológica de las unidades de producción de tomate bajo invernadero en Puebla. Rev. Mex. Cienc. Agríc. 11(5):979-992. https://doi.org/10.29312/remexca.v11i5.2010. [ Links ]

NOM. 2002. Norma Oficial Mexicana. NOM-021-RECNAT-2000 establece las especificaciones de fertilidad, salinidad y clasificación de suelos. Estudios, muestreo y análisis. Diario oficial de la federación. http://dof.gob.mx/nota-detalle.php?codigo=756861&fecha=07/12/200 . [ Links ]

Sánchez-González, M. J.; Sánchez-Guerrero, M. C.; Medrano, E.; Porras, M. E.; Baeza, E. J.; García, M. L. y Lorenzo, P. 2014. Efectos de la salinidad y el enriquecimiento carbónico en invernadero sobre la bioproductividad y el contenido de nutrientes en un cultivo de tomate híbrido Raf (cv. Delizia). Acta Hortic. 66:78-84. http://www.sech.info/ACTAS/index.php?d=main. [ Links ]

SIAP. 2021. Sistema de información agrícola y pesquera. Producción anual agrícola. https://www.gob.mx/siap/acciones-y-programas/produccion-agricola-33119. [ Links ]

Yasuor, H.; Yermiyahu, U. and Ben-Gal, A. 2020. Consequences of irrigation and fertigation of vegetable crops with variable quality water: Israel as a case study. Agric. Water Manag. 242:106362. 10 p. https://doi.org/10.1016/j.agwat.2020.106362. [ Links ]

Zörb, C.; Geilfus, C. M. and Dietz, K. J. 2019. Salinity and crop yield. Plant biology. 21:31-38. https://doi.org/10.1111/plb.12884. [ Links ]

Received: July 01, 2023; Accepted: August 01, 2023; Published: September 08, 2023

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