Relationship between chlorophyll and nitrogen concentration, and fresh matter production in basil ‘Nufar’ (Ocimum basilicum) with three handheld chlorophyll meter readings: SPAD, atLEAF and MC-100

Ontiveros-Capurata, Ronald Ernesto; Juárez-López, Porfirio; Mendoza-Tafolla, Rodrigo Omar; Alia-Tejacal, Irán; Villegas-Torres, Oscar Gabriel; Guillén-Sánchez, Dagoberto; Cartmill, Andrew D.; Ontiveros-Capurata, Ronald Ernesto; Juárez-López, Porfirio; Mendoza-Tafolla, Rodrigo Omar; Alia-Tejacal, Irán; Villegas-Torres, Oscar Gabriel; Guillén-Sánchez, Dagoberto; Cartmill, Andrew D.

doi:10.5154/r.rchsh.2021.09.018

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Revista Chapingo. Serie horticultura

versión On-line ISSN 2007-4034versión impresa ISSN 1027-152X

Rev. Chapingo Ser.Hortic vol.28 no.3 Chapingo sep./dic. 2022 Epub 13-Dic-2022

https://doi.org/10.5154/r.rchsh.2021.09.018

Scientific articles

Relationship between chlorophyll and nitrogen concentration, and fresh matter production in basil ‘Nufar’ (Ocimum basilicum) with three handheld chlorophyll meter readings: SPAD, atLEAF and MC-100

Ronald Ernesto Ontiveros-Capurata¹
http://orcid.org/0000-0002-5094-0469

Porfirio Juárez-López²
http://orcid.org/0000-0002-4241-1110

Rodrigo Omar Mendoza-Tafolla²
http://orcid.org/0000-0002-8079-1468

Irán Alia-Tejacal²
http://orcid.org/0000-0002-2242-2293

Oscar Gabriel Villegas-Torres²
http://orcid.org/0000-0001-9885-3906

Dagoberto Guillén-Sánchez²
http://orcid.org/0000-0001-5958-4969

Andrew D. Cartmill³
http://orcid.org/0000-0001-9721-3114

^¹Cátedra CONACYT - Instituto Mexicano de Tecnología del Agua. Paseo Cuauhnáhuac, núm. 8532, Jiutepec, Morelos, C. P. 62550, MÉXICO.

^²Universidad Autónoma del Estado de Morelos, Posgrado en Ciencias Agropecuarias y Desarrollo Rural. Av. Universidad, núm. 1001, Cuernavaca, Morelos, C. P. 62210, MÉXICO.

^³University of Wisconsin-Platteville. University Plaza, Platteville, Wisconsin, 53818, UNITED STATES OF AMERICA.

Abstract

Determinations of nitrogen (N) and chlorophyll (Chl) by destructive methods are precise but time-consuming and frequently expensive. The objective of this study was to determine the relationship between SPAD, atLEAF, and MC-100 readings with the concentrations of Chl, N, and fresh matter (FM) in basil ‘Nufar’. In addition, we determined the relationship of the N concentration with fresh matter (FM). The plants were irrigated with five levels of N (0, 4, 8, 12, and 16 mEq·L^-1 of NO₃) based on a modified Steiner solution for 42 days after transplant. Plants were evaluated weekly with SPAD, atLEAF and MC-100 portable chlorophyll meters in the greenhouse, while FM and the concentration of Chl and N were determined in the laboratory using conventional techniques. The relationship between SPAD readings, Chl, N, and FM was strong, positive, linear, and significant, with correlation coefficients (R²) between 0.94 and 0.98. For atLEAF and MC-100 readings, R² values were 0.96 to 0.99 and 0.96 to 0.99, respectively. The relationships between SPAD, atLEAF and MC-100 readings were strong, positive, and significant, with R² values of 0.98. Similar behavior was shown by the relationship of N concentration and FM with R² of 0.88. With these results, we conclude that SPAD, atLEAF, and MC-100 can be used to estimate the nutrient status of N in a non-destructive, rapid and reliable manner during basil production.

Keywords non-destructive analysis; aromatic plant, soilless culture

Resumen

Las determinaciones de nitrógeno (N) y clorofila (Chl) por métodos destructivos son precisas, pero demandantes en tiempo y frecuentemente costosas. El objetivo de este estudio fue determinar la relación entre las lecturas SPAD, atLEAF y MC-100, y las concentraciones de Chl, N y materia fresca (MF) en albahaca ‘Nufar’. Las plantas se irrigaron con cinco niveles de N (0, 4, 8, 12 y 16 mEq·L^-1 de NO₃), basados en una solución de Steiner modificada, durante 42 días después del trasplante. Las plantas se evaluaron semanalmente en el invernadero con los medidores portátiles de clorofila SPAD, atLEAF y MC-100. La MF, la Chl y el N se determinaron en laboratorio mediante técnicas convencionales. La relación entre las lecturas SPAD, la Chl, el N y la MF fue lineal, positiva y significativa, con coeficientes de determinación (R²) entre 0.94 y 0.98. Para las lecturas atLAEF y MC-100, los valores de R² fueron 0.96 a 0.99 y 0.96 a 0.99, respectivamente. Las relaciones entre las lecturas SPAD, atLEAF y MC-100 resultaron positivas y significativas, con valores de R² de 0.98. Un comportamiento similar se presentó en la relación de concentración de N y MF, con R² de 0.88. Con base en estos resultados, se concluye que los medidores SPAD, atLEAF y MC-100 se pueden utilizar para estimar los estatus de N de forma no destructiva, rápida y confiable durante la producción de albahaca.

Palabras clave análisis no destructivo; plantas aromáticas; cultivo sin suelo

Introduction

Nitrogen (N) is an essential and indispensable element for plant growth and development because it is an integral component of proteins, amino and nucleic acids, and chlorophyll (Chl). Chl generates the green color of plants and is an essential pigment for photosynthesis (^{Taiz, Zeiger, Moller, & Murphy, 2014}). The Chl concentration of the leaf is closely correlated with the concentration of N in the plant (^{Zebarth, Younie, Paul, & Bittman, 2002}). Therefore, monitoring Chl and N concentrations may help maximize nutrient management for optimal plant growth and yield of agricultural and horticultural crops (^{Argenta et al., 2003}; ^{Cruz-Álvarez et al., 2020}).

Determinations of N and Chl by destructive methods are precise but time-consuming and frequently expensive (^{Kalaji et al., 2017}). In contrast, non-destructive portable meters have been successfully used for some plant species to estimate Chl and N (^{Cunha, Katz, Sousa, & Martinez-Uribe, 2015}) and thereby allow for the monitoring of Chl and N in the same leaf, in different portions of the crop production cycle (^{Kalaji et al., 2017}).

The SPAD 502 Plus chlorophyll meter (Konica Minolta^®, Japan) may be used for the rapid and non-destructive determination of the relative concentration of Chl in the leaf (^{Ali, Al-Ani, Eamus, & Tan, 2007}). The transmission of light through the leaf is measured at 650 and 940 nm, and the wavelength of 650 nm coincides with the spectral region of the maximum Chl activity. The transmittance at 940 nm is used to compensate for factors such as the moisture content of the leaf (^{Padilla, Gallardo, Peña-Fleitas, de Souza, & Thompson, 2018b}). Therefore, the SPAD readings are related to the concentration of leaf Chl (^{Basyouni, Dunn, & Goad, 2015}; ^{Uddling, Gelang-Alfredsson, Piikki, & Pleijel, 2007}).

The atLEAF Plus chlorophyll meter (FT Green LLC®, USA) works similarly to the SPAD meter. However, it uses a wavelength of 660 nm instead of 650 nm (^{Padilla et al., 2018b}), and it is a cheaper alternative when compared to the SPAD meter (^{de Souza et al., 2019}). The MC-100 chlorophyll meter (Apogee Instruments Inc. Logan, USA) records the relative concentration of Chl at the wavelengths of 653 and 931 nm in an area of approximately 64 mm² (^{de Souza et al., 2019}). It has been used to determine Chl concentration in leaves and evaluate nutritional stress and crop optimization (^{Padilla et al., 2018a}).

The concentration of Chl and N determined in the laboratory correlates with SPAD readings in crops. For example, this technique has been used in corn (Zea mays), wheat (Triticum aestivum) (^{Hurtado et al., 2010}), and vegetable crops, including tomatoes (Solanum lycopersicum) (^{Macedo-Ferreira, Barbosa-Ferreira, Rezende-Fontes, & Pires-Dantas, 2006}) and cabbage (Brassica oleracea). In contrast, the atLEAF system has been reported to have high correlations for crops including corn and wheat (^{Zhu, Tremblay, & Liang, 2012}) and ornamental horticultural crops, including poinsettia (Euphorbia pulcherrima) (^{Dunn, Singh, & Goad, 2018a}) and aromatic herbs such as sage (Salvia splendens) (^{Dunn, Singh, Payton, & Kincheloe, 2018b}). The MC-100 meter is relatively new, i.e., ^{de Souza et al. (2019)} have reported statistically significant correlations in sweet pepper (Capsicum annuum).

Basil (Ocimum basilicum) is a major global crop, accounting for approximately 14.9 million tons of production worldwide (^{Food and Agriculture Organization of the United Nations [FAO], 2019}). In Mexico, basil is an important leafy vegetable crop, ranking third in production, with 352.78 tons produced (^{Servicio de Información Agroalimentaria y Pesquera [SIAP], 2019}).

In leafy vegetables and aromatic herbs, the green color of the leaves is essential as a quality indicator for fresh consumption and marketability. Therefore, determining N and Chl concentration in leaves in situ over time represents a valuable crop production tool to maximize quality and marketability. The objective of this study was to determine the relationship between SPAD, atLEAF, and MC-100 readings with Chl, N, and fresh matter (FM) in basil ‘Nufar’.

Material and methods

Site study and plant material

The experiment was carried out in a tunnel greenhouse at the Facultad de Ciencias Agropecuarias belonging to the Universidad Autónoma del Estado Morelos, located in Cuernavaca, Morelos, Mexico (18° 58’ 51’’ N and 99° 13’ 55’’ W, at 1,866 m a. s. l.) during May and June 2019.

The tunnel greenhouse was covered with white plastic and anti-aphids mesh on the side walls. The temperature, relative humidity, and solar radiation values were recorded every 5 min with a datalogger for the duration of the study (model U12-012, Hobo®, Onset®, USA). The maximum and minimum temperatures recorded were 42 and 14 °C, respectively, with an average of 26 °C. Relative humidity was 80, 20, and 49 %, corresponding to maximum, minimum, and average. The average solar radiation was 545 µmol·m^-2·s^-1.

Basil ‘Nufar’ seeds (Johnny's Selected Seeds, USA) were sown on April 1, 2019, into a 200-cavity polystyrene tray filled with BM2 Berger® commercial seed germination substrate. Thirty days later, seedlings were transplanted into 8 L polyethylene bags, which contained volcanic rock (locally called tezontle) as a substrate with a granulometry of 1 to 10 mm (^{Cruz-Crespo, Sandoval-Villa, Volke-Haller, Can-Chulim, & Sánchez-Escudero, 2012}).

Treatments and measurement of variables

The plants were irrigated daily for 21 days from transplanting with 0.5-1.0 L of ^{Steiner (1984)} nutrient solution, modified to apply five levels of nitrate (0, 4, 8, 12, and 16 mEq·L^-1) (^{Mercado-Luna et al., 2010}). Plants were irrigated to achieve a 15 to 20 % leachate volume to avoid salt accumulation. Micronutrients were added to the nutrient solution as chelates at 80 g·m^-3 of a commercial product (Ultrasol® micro Rexene SQM). The pH of the nutrient solutions was adjusted to 5.6 - 6.0 with sulfuric acid.

The portable equipment of Chl SPAD-502 Plus Minolta, atLEAF Chl Plus, and MC-100 Apogee Instruments Inc. (Figure 1) were used for on-site measurements, according to the methodology suggested by ^{León, Viña, Frezza, Chaves, and Chiesa (2007)} and ^{de Souza et al. (2019)}. Readings were taken between 11:00 AM and 12:00 PM; the average of each reading was obtained from 10 records with six replications. The Chl concentration in the laboratory was determined on the same leaves sampled with the portable meters. Immediately after finishing the measurements in situ, fresh matter (FM) was harvested to assess their weight with an OHAUS scale. These samples were then dried in a forced-air oven (F210, Felisa®, México) at 70 °C for 72 h, ground, and the total N was quantified by the micro Kjeldahl method (^{Kalra, 1998}). Finally, the concentration of Chl (mg·g^-1) was determined with the spectrophotometric method described by ^{Mackinney (1941)} and ^{Wettstein (1957)}. All determinations were performed weekly from 7 to 42 days after transplantation in situ and laboratory.

Figure 1 Use of SPAD 502 Plus (a), atLEAF (b) and MC-100 (c) to measure relative chlorophyll concentration in basil ‘Nufar’.

Design and statistical analysis

A completely randomized experimental design was used with five treatments (0, 4, 8, 12, and 16 mEq·L^-1 of NO₃) and six replications (30 pots per 7 weeks = 210 pots in total). The experimental unit was a pot containing one plant (Figure 2). With the values obtained in situ and in the laboratory, correlations and linear regressions were made of the SPAD, atLEAF, and MC-100 readings versus Chl, N, and FM with the software SigmaPlot graphs v12.5. The data obtained 42 days after transplanting were subjected to an analysis of variance and Tukey's mean comparison test (P ≤ 0.01) using the SAS ver. 9.1 software (^{SAS, 2004}).

Figure 2 Basil ‘Nufar’ growth as a function of NO₃-N level at 42 days after transplanting.

Results and discussion

Response to N levels

Differences (P ≤ 0.01) were observed for SPAD, atLEAF, and MC-100 readings with the concentrations of N and chlorophyll, and fresh matter as a function of N applied to basil ‘Nufar’ (Table 1).

Table 1 SPAD, atLEAF, MC-100 readings, fresh matter (FM), concentrations of nitrogen (NO₃-N) and chlorophyll in basil ‘Nufar’ at 42 days after transplanting.

N Level (mEq·L^-1)	SPAD	atLEAF	MC-100	Nitrogen (%)	Chlorophyll (mg·g^-1)	FM (g·plant^-1)
0	42.4 d^z	44.3 d	44.2 c	1.34 d	2.85 c	111.1 d
4	43.6 d	45.3 d	46.1 c	1.41 d	3.01 c	121.6 d
8	47.9 c	50.5 c	48.9 bc	1.85 c	3.21 b	145.3 c
12	52.7 b	55.7 b	52.1 b	2.11 b	3.56 b	185.4 b
16	56.8 a	59.1 a	58.3 a	2.63 a	3.98 a	217.3 a
CV (%)	9.3	11.4	10.3	7.1	6.9	12.2

^zMeans with the same letter within each column do not differ statistically (Tukey, P ≤ 0.01). CV = coefficient of variation.

For the variables, an increase was observed when increasing the nitrogen level in the nutrient solution. ^{Basyouni et al. (2015)} reported a similar trend for nitrogen and SPAD readings in poinsettia (Euphorbia pulcherrima) leaves. ^{Padilla et al. (2018a)} reported a statistical difference in nitrogen nutrition levels in sweet pepper; the higher the amount of N applied, the higher the yields.

Correlation between SPAD, atLEAF, and MC-100 readings versus Chl, N, and FM

SPAD, atLEAF, and MC-100 versus Chl

The correlation to the linear regression model between SPAD readings and the concentration of Chl (Table 2) was highly significant and positive (P = 0.01, R² = 0.96). These results are similar to those reported by ^{Fenech-Larios et al. (2009)}, who found a high correlation between SPAD readings and Chl concentration (R² = 0.98) in basil seedlings. Similar values (R² = 0.99) have been reported by ^{Mendoza-Tafolla et al. (2019)} in romaine lettuce (Lactuca sativa L.). However, the correlations of the present study are superior to those reported by ^{Martín et al. (2007)}. They, in laurustine (Viburnum tinus), tobira (Pittosporum tobira) and arbutus (Arbutus unedo), found coefficients of determination between 0.13 and 0.27. We suggest that the lower correlation coefficients reported by ^{Martín et al. (2007)} reflect the physiological difference between woody and herbaceous species.

Table 2 Linear regression equations, coefficients of determination, and mean square error (MSE) values for SPAD, atLEAF, and MC-100 readings with the chlorophyll (Chl) concentration in basil ‘Nufar’.

Correlation	Regression equation	R²	MSE
SPAD and Chl	Chl = 0.0079 SPAD + 0.0650	0.97**	0.06
atLEAF and Chl	Chl = 0.0086 atLEAF + 0.0036	0.93**	0.03
MC-100 and Chl	Chl = 0.0121 MC-100 - 0.0922	0.96**	0.04

** = coefficient of determination (R²) significant P ≤ 0.01.

The R² value for the atLEAF readings with Chl was 0.93. These results indicate a more significant adjustment to the linear regression model when compared to those reported by ^{Zhu, Tremblay, and Liang (2011)}. They obtained coefficients of determination ranging from 0.72 to 0.88 in corn, wheat, barley (Hordeum vulgare), potato (Solanum tuberosum), and canola (Brassica napus). ^{Hebbar et al. (2016)} reported R² between 0.68 to 0.95 in coconut palm leaves (Cocos nucifera). For the MC-100 meter, the coefficient of determination was 0.96 for a linear regression model. ^{Padilla et al. (2018a)} reported R² ranging from 0.76 to 0.94 in sweet pepper. The concentration of Chl in basil leaves can be estimated with sufficient accuracy from the SPAD, atLEAF, and MC-100 readings with the linear regression equation (Figure 3).

Figure 3 Linear regression between the SPAD, atLEAF, and MC-100 readings with the concentration of chlorophyll in leaves of basil ‘Nufar’.

SPAD, atLEAF, and MC-100 versus N

The relationship between SPAD, atLEAF, and MC-100 was highly significant with the N concentration in basil ‘Nufar plants (Figure 4). They had an adjustment to the linear regression model with R² values of 0.95, 0.97, and 0.89, respectively (Table 3).

Figure 4 Linear regression between the SPAD, atLEAF, and MC-100 readings with the nitrogen concentration in basil ‘Nufar’.

Table 3 Linear regression equations, coefficients of determinatios, and mean square error (MSE) values for SPAD, atLEAF, and MC-100 readings with the nitrogen (N) concentration in basil ‘Nufar’.

Correlation	Regression equation	R²	MSE
SPAD and N	N = 0.0336 SPAD + 0.1751	0.95**	0.03
atLEAF and N	N = 0.0378 atLEAF - 0.1298	0.97**	0.03
MC-100 and N	N = 0.0502 MC-100 - 0.4549	0.89**	0.05

** = coefficient of determination (R²) significant P ≤ 0.01.

^{Ali et al. (2007)} found R² values ranging from 0.86 to 0.94 for the relationship between the SPAD meter and nitrogen concentration in the greenhouse tomato crop. ^{Dunn et al. (2018b)} reported R² values of 0.92 for the relationship between atLEAF and N in sage (Salvia officinalis) seedlings, and ^{de Souza et al. (2019)} compared the atLEAF and MC-100 meters to determine the concentration of N in sweet pepper obtaining R² ranging from 0.81 and 0.94 for both meters.

It is important to mention that most of the studies where chlorophyll meter values are reported do not include correlation analysis with chlorophyll and nitrogen values obtained from the laboratory, which causes limitations to accurately determine the concentration of these two variables, since the readings of the chlorophyll meters are dimensionless. Therefore, the correlations reported in the present study represent the correct procedure for estimating chlorophyll and nitrogen concentration in basil. Once calibration with correlation analysis has been performed on the species of interest, it is possible to make predictions of chlorophyll and nitrogen content during the growing cycle (^{Ruiz-Espinoza et al., 2010}).

SPAD, atLEAF, and MC-100 versus FM

The correlation between the SPAD readings and FM (Figure 5) was significant and positive with a determination coefficient of 0.88 (Table 4). These results are similar to those of ^{Cunha et al. (2015)}, who obtained R² between 0.85 and 0.96 in the relationship between SPAD and fresh arugula (Eruca vesicaria). ^{Cho, Oh, Oh, and Son (2007)} suggested that SPAD readings can be used to estimate the performance of FM and predict the yield of cucumber cultivation (Cucumis sativus).

Figure 5 Linear regression between the SPAD, atLEAF, and MC-100 readings with fresh matter in basil ‘Nufar’.

Table 4 Linear regression equations, correlation coefficients of determination, and mean square error (MSE) values for SPAD, atLEAF, and MC-100 readings with fresh matter (FM) in basil ‘Nufar’.

Correlation	Regression equation	R²	MSE
SPAD and FM	FM = 4.3016 SPAD - 64.9720	0.88**	0.06
atLEAF and FM	FM = 6.1576 atLEAF - 13.7030	0.87**	0.02
MC-100 and FM	FM = 4.9606 MC-100 - 10.777	0.94**	0.05

** = Coefficient of determination (R²) significant P ≤ 0.01.

The correlation between atLEAF readings and FM (Figure 5) was significant and presented an excellent adjustment to the linear regression, with an R² of 0.87 (Table 4). The results were similar to those reported by ^{Dey, Sharma, and Meshram (2016)}, who obtained R² values of 0.95 in betel (Piper betel). The values obtained with the MC-100 were highly significant, with R² of 0.94 for a linear regression model.

Linear regression between SPAD, atLEAF, and MC-100 readings

The correlation between the SPAD and atLEAF readings was highly significant, with an R² of 0.94 (Table 5; Figure 6a). These results are similar to those reported by ^{Dunn et al. (2018a)}, who obtained R² ranging from 0.64 to 0.90 between SPAD and atLEAF readings on poinsettia leaves. In addition, ^{Zhu et al. (2011)} found significant correlations between the SPAD and atLEAF readings for corn, barley, and potatoes, with intervals for the determination coefficient ranging from 0.90 and 0.92.

Table 5 Linear regression equations, coefficients of determination, and mean square error (MSE) values for the relationship between the SPAD, atLEAF, and MC-100 readings in basil ‘Nufar’.

Correlation	Regression equation	R²	MSE
SPAD and atLEAF	SPAD = 0.8852 atLEAF + 8.1197	0.97**	0.06
SPAD and MC-100	SPAD = 0.6286 MC-100 +13.675	0.94**	0.03
atLEAF and MC-100	atLEAF = 0.6982 MC-100 + 8.3040	0.94**	0.04

** = coefficient of determination (R²) significant P ≤ 0.01.

Figure 6 Linear regression between portable meter readings in leaves of basil ‘Nufar’: a) relationship between SPAD readings with atLEAF and MC-100, and b) the relationship between atLEAF and MC-100 readings.

In a linear regression model, the R² value between the SPAD and MC-100 was 0.94 (Figure 6b). Results were similar to those obtained by ^{Padilla et al. (2018a)}, who reported R² ranging from 0.90 to 0.95 in sweet pepper. The relationship between atLEAF and MC-100 presented values of R² equal to 0.94.

The present study demonstrates that handheld portable chlorophyll meters such as SPAD, atLEAF, and MC-100 can estimate N, Chl, and FM accurately and quickly. However, the three meters tested show similar results, so when deciding to use one or the other, it will be essential to consider different parameters such as price since the difference is considerable. In addition, to the best of our knowledge, this is the first report to date using the AtLEAF and MC-100 meters to determine Chl content, N status, and FM production of basil.

Relationship between nitrogen concentration and fresh matter

The relationship between N concentration and FM (Figure 7) was significant (P < 0.01) and resembles a linear regression with a slope of 132.78 and intercept of -92.65, where FM is the dependent variable and N the independent variable; the R² value was 0.88, and the mean square error (MSE) was 0.03. These results are similar to those obtained by ^{Arabaci and Bayram (2004)}, and ^{Hordofa et al. (2021)}, who reported an increase in the amount of leaf production in basil concerning N fertilization since it is an essential primary nutrient that improves yield and is necessary for the construction of amino acids, nucleotides and nucleic acids.

Figure 7 Linear regression between nitrogen concentration (N) and fresh matter (FM) in basil ‘Nufar’.

These results confirm that the ratio of fresh biomass versus nitrogen content is of utmost importance in the case of leafy crops such as basil. Both can be estimated quickly and accurately from leaf reflectance characteristics (^{Ruiz-Espinoza et al., 2010}). Furthermore, it reinforces the claim that chlorophyll meters are an effective tool for rapid and non-destructive estimation of FM weight in leafy crops.

Conclusions

The SPAD, atLEAF, and MC-100 meters predict, in a non-destructive, fast, and accurate way, Chl and N concentrations and FM production in basil ‘Nufar’, based on linear regression equations. The SPAD readings had positive and significant linear correlations, with Chl concentration (R² = 0.97), N (R² = 0.95) and FM (R² = 0.88). Also, atLEAF readings had a linear correlation with Chl concentration (R² = 0.93), N (R² = 0.97) and FM (R² = 0.87), and the MC-100 readings had a similar linear correlation with the concentration of Chl (R² = 0.96), N (R² = 0.89) and FM (R² = 0.94). The relationship between the SPAD readings with atLEAF and MC-100 was also high, positive, and with significant linear correlations (R² = 0.97 and 0.94 respectively), as was also the case with the correlation between atLEAF and MC-100 (R² = 0.94). The SPAD, atLEAF, and MC-100 readings allow for the early estimation of the Chl and N status of the plant used to program fertilizer application more efficiently during basil cultivation.

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Received: August 07, 2021; Accepted: July 06, 2022

^*Corresponding author: porfirio.juarez@uaem.mx, tel. ‭777 103 3426.‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬

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Revista Chapingo. Serie horticultura

versión On-line ISSN 2007-4034versión impresa ISSN 1027-152X

Rev. Chapingo Ser.Hortic vol.28 no.3 Chapingo sep./dic. 2022 Epub 13-Dic-2022

https://doi.org/10.5154/r.rchsh.2021.09.018