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1155 
Original Article 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

EFFECT OF REDUCING CHEMICAL FERTILIZER AND USING 
ORGANOMINERAL FERTILIZATION ON NUTRITIONAL BEHAVIOR AND 

VEGETATIVE GROWTH OF OLIVE TREES  
 

EFEITO DA REDUÇÃO DA ADUBAÇÃO QUÍMICA COM FERTILIZAÇÃO 
ORGANOMINERAL NO COMPORTAMENTO NUTRICIONAL E CRESCIMENTO 

VEGETATIVO DE OLIVEIRAS  
 

Rodrigo Amato MOREIRA
1
; Maria do Céu Monteiro da CRUZ

2
; Jéssica de OLIVEIRA

3
;  

Adelson Francisco de OLIVEIRA
4
 

1. Professor, Doutor, Instituto Federal do Norte de Minas - IFNMG, Januária, MG, Brasil. amatomoreira@yahoo.com.br; 2. Professora, 
Doutora, Universidade Federal dos Vales do Jequitinhonha e Mucuri - UFVJM, Diamantina, MG, Brasil; 3. Mestranda do Programa de 

Pós-Graduação em Produção Vegetal, Universidade Federal dos Vales do Jequitinhonha e Mucuri - UFVJM, Diamantina, MG, Brasil. 4. 
Pesquisador, Doutor, Empresa de Pesquisa Agropecuária de Minas Gerais - EPAMIG, Lavras, MG, Brasil; 

 
ABSTRACT: This research was conducted with the aim of evaluating the nutritional behavior and vegetative 

growth of two olive tree varieties with the reduction of chemical fertilization and the application of organomineral 
fertilizer. Three-year-old trees of varieties ‘Barnea’ and ‘Grappolo 541’ were used and cultivated on Quartzarenic Neosol 
in the field. The split-plot scheme was used, with a 4 x 2 factorial design, with the factors of four fertilizations and two 
varieties and the subplot of evaluation years. The four fertilizations consisted of 100%, 75%, 50% and 0% of the chemical 
fertilizer recommended for olive trees. Treatments were arranged in a randomized complete block design, with three 
blocks and three plants per plot. The organomineral fertilizer was used on all of the plants. Leaf samples and vegetative 
growth were evaluated in July 2012 and June 2013. The nutritional behavior of olive tree varieties ‘Barnea’ and ‘Grappolo 
541’ was unchanged with a 50% reduction of chemical fertilizer and the application of organomineral fertilizer. The 
variety ‘Barnea’, with habit of rapid growth, had lower foliar nutrient concentrations. A 64.5% reduction of the chemical 
fertilizer with the application of the organomineral fertilizer had no effect on the vegetative growth of the olive tree variety 
‘Grappolo 541’. 

 
KEYWORDS: Olea europaea. Chemical nutrition. ‘Barnea’. ‘Grappolo 541’. 

 
INTRODUCTION 

 
The olive tree (Olea europaea L.) is one of 

the most widespread fruit tree species in regions 
with a Mediterranean climate (PROIETTI et al., 
2015). However, there are areas in Brazil that have 
favorable climatic conditions for its production, 
such as the South and Southeast of the country, 
which has attracted some farmers (MARTINS et al., 
2012; CARVALHO et al., 2014). 

Although the olive tree is considered a 
rustic species, it needs to be submitted to adequate 
levels of nutrients in its early stage of growth, 
because the nutrients perform essential functions in 
vegetative growth and reproductive development 
(CARVALHO et al., 2013). The issuance of 
inflorescences is important to tree development and 
fruit quality, as well as the quality of the oil 
(FERNÁNDEZ-ESCOBAR et al., 2006; 
CHOULIARAS et al., 2009; BOUSSADIA et al.; 
2010).  

Thus, due to the knowledge of the effect of 
nutrients on the development and productivity of 
olive groves, the excessive application of chemical 
fertilizers has occurred. This is often done without 

considering the phenological variability of plants 
and features related to the area of cultivation, 
resulting in increased production costs and 
environmental risks (BOUSSADIA et al., 2010). 

To ensure the sustainability of agricultural 
systems, some farmers, encouraged by researchers, 
are using fertilizers with less environmental impact 
and lower cost. These fertilizers come from organic 
materials available in the environment and do not 
compromise the quality of production. In the case of 
the olive tree, whose cultivated area is expanding in 
Brazil, it is important to adopt practices to facilitate 
crop management. 

Therefore, the organomineral fertilizers 
presented good results in agriculture, improving the 
efficiency of the plant uptake and reducing the use 
of chemical fertilizers and production costs 
(FERNANDES et al., 2007). Organomineral 
fertilizers contain sources of both organic and 
chemical fertilizers, which helps reduce nutrient 
losses by increasing the proliferation of 
microorganisms and the use of fertilizer in the soil, 
which represents a significant reduction in costs to 
farmers. 

Received: 01/12/16 
Accepted: 05/05/17 



1156 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

Actual results in some studies showed the 
benefits of organomineral fertilization in agriculture, 
such as in the production of coffee crop 
(FERNANDES et al., 2007), the growth of rootstock 
‘Rangpur’ lime (CARNEIRO et al., 2011), flower 
production (FARIAS et al., 2013) and sugarcane 
rations (SANTOS et al., 2014). However, the effect 
of fertilizer is linked to the fertilizer formulation and 
the species, or even the variety, that is being 
fertilized. 

Thus, this study was done to evaluate the 
nutritional behavior and the vegetative growth of 
two olive trees varieties with the reduction of 
chemical fertilization and the application of 
organomineral fertilizer. 

 

MATERIALS AND METHODS 
 
The research was conducted in Diamantina, 

Minas Gerais, Brazil, located at 18° 14’ 56” S and 
43° 36’ 0” W, at an altitude of 1,384 m. The climate 
is classified as humid temperate, with dry winters 
and rain in summers. The area has an annual 
average temperature of 18 °C and approximately 
1,400 mm of rainfall (VIEIRA et al., 2010). Low 
temperatures occur from May to August, and there 
is more rainfall from November to January. During 
the experimental period, the variations of 
temperature and precipitation in the region were 
recorded (Figure 1). The experimental area was 
classified as Quartzarenic Neosol, with 83% sand, 
10% clay and 7% silt. 

 

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Sep-11 Nov-11 Ja n-12 Ma r-12 Ma y-12 Jul-12 Sep-12 Nov-12 Ja n-13 Ma r-13 Ma y-13 Jul-13

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it
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ti
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n
 (m

m
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T
em

p
er

a
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C
)

Precipitation mean temperature

maximum temperature minimum temperature

 
Figure 1. Mean, maximum and minimum temperatures (°C) and monthly precipitation (mm) during the 

evaluation period in Diamantina, Minas Gerais, Brazil. 
 
The planting of olive trees was conducted in 

June 2010, with a 5 m spacing between rows and 3 
m between plants. The nursery olive trees were 
obtained from the Experimental Farm of EPAMIG 
in Maria da Fé, MG, Brazil, and they were two 
years old at the time of planting. 

The experiment started in October 2011, 
and the fertilization was based on the soil chemical 
characteristics at eight months after planting (Table 
1). 

 
Table 1. Soil chemical characteristics at eight months after planting at a depth of 0-20 cm, UFVJM, Campus 

JK, Diamantina, Minas Gerais, Brazil. 

Depth 
pH P K Ca Mg Al+3 H +Al 

(cm) 
H2O ------- mg dm

-3 ------- ----------------------- cmolc dm
-3 ---------------- 

0-20 6,2 12,59 30,7 1,36 0,44 0,01 1,5 

Depth SB t T V m M.O 
(cm) ----------- cmolc dm

-3 --------- ---------- % -------- ------- dag kg-1 ------ 

0-20 1,88 1,89 3,38 56 1 1,2 
SB – sum of bases; t – cation exchange capacity; T – cation exchange capacity at pH 7.0; V – base saturation; m – aluminum saturation 
index; and OM – organic matter. 
 

The olive varieties used were ‘Barnea’ and 
‘Grappolo 541’. ‘Barnea’ is characterized as a 
vigorous and erect plant, while ‘Grappolo 541’ has 

medium vigor and a well-developed canopy 
circumference. 

The experiment was conducted in a split 
plot design, in a 4 x 2 factorial design. There were  



1157 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

four fertilization levels, 100%, 75%, 50% and 0% of 
the chemical fertilizer recommended for olive trees 
(MESQUITA et al., 2006), with organomineral 
fertilizer used in all fertilizations, and two varieties 
of olive tree, ‘Grappolo 541’ and ‘Barnea’, in each 
subplot. The evaluation periods were July 2012 
(eight months after the application of organomineral 
fertilizer) and June 2013 (eight months after the 
application of organomineral fertilizer in the second 
year of assessment). Treatments were arranged in a 
randomized complete block design, with three 
replications and three plants per plot. 

The organomineral fertilizer used in the 
experiment was developed by the company Ceres 
Tecnologia Agrícola (Lavras, Minas Gerais, Brazil) 
and was composed of organic natural sources 
(laying hen manure and coffee husk), inorganic 
sources (magnesium silicate, calcium sulfate and 
partially soluble phosphorus source) and calcified 
seaweed (Lithothamnium sp.). The chemical 
analysis of this product was 1.55% N, 4.08% P2O5, 
3.24% K2O, 11.03% Ca, 2.25% Mg, 0.006% B, 
0.029% Cu, 0.024% Mn, 0.018% Zn, 0.22% Fe, 
1.03% SiO2, and 2.64% S-SO4. 

The fertilization was based on a soil 
analysis and the recommendation for olive trees 
proposed by Mesquita et al. (2006), taking into 
account that during the first and second years of the 
experiment, the plants had already been in the field 
for one year and two years. Thus, the first-year 
fertilizer recommendation, which corresponded to 
100% of the chemical fertilizer, was 320 g of 
ammonium sulfate and 50 g of potassium chloride. 
In the second year, the fertilizer recommendation 
was 380 g of ammonium sulfate and 66 g chloride 
potassium. The fertilizer was applied in three 
installments, in the months of November, December 
and January (the months of higher rainfall). 

The monitoring of pests and diseases was 
done periodically throughout the crop cycle.  Pests 
and diseases were controlled using products with 
low environmental impact, such as copper fungicide 
that was registered for use in fruit species. 

Weeds in the crop area were controlled with 
a brush cutter, and mulch was placed on the spaces 
between the rows. 

For the determination of the levels of 
nutrients in the leaves, samples of mature, fully 
expanded leaves at the middle of the plant and the 
median part of the branch from all parts of the plant 
were collected in July 2012 and June 2013. Samples 
were composited for approximately 30 to 40 leaves 
with petioles. 

The material was immediately washed and 
dried in an oven with forced air circulation at 65 °C 

for 72 hours until a constant weight. After this 
period, the leaves were ground in a Wiley-type mill 
and subjected to a chemical analysis to determine 
the levels of nutrients. The chemical analysis was 
performed according to the methodology proposed 
by Malavolta et al. (1997). 

The increment in height (with a graduated 
ruler placed vertically next to the plant), increment 
in stem diameter (at 20 cm height from ground with 
a caliper), and surface production were evaluated by 
measuring the diameter cup in two perpendicular 
positions, corresponding to its largest (D1) and 
smallest widths (D2). The formula for calculating 
surface fruiting is SF = Π DH, where D is the 
average of two diameters (D1 and D2) and H is the 
height of the canopy (RÍO; CABALLERO, 2006). 

The data increments in the height and stem 
diameter were calculated by the difference in height 
found at the time evaluated from the previous time 
to July 2012 and June 2013. The objective of this 
evaluation was to characterize the differences 
between varieties and their capacity development in 
the area of cultivation due to the application of 
different fertilizers. 

The data were subjected to analysis of 
variance and regression to compare the treatments. 
The choice of models was based on the ability to 
explain the biological phenomenon in question, the 
coefficient of determination and significance of the 
regression coefficients using the t-test at 5% 
probability of error. 

 
RESULTS AND DISCUSSION 

 
The levels of N in the leaves of the variety 

‘Barnea’ did not differ after fertilization, with values 
of 16.9 g kg-1 in July 2012 and 24.0 g kg-1 in June 
2013 (Figure 2A). In the variety ‘Grappolo 541’, 
there was a 44.3% increase in the levels of N in the 
leaves eight months after fertilization (July 2012) in 
the plants that received 100% of chemical fertilizer 
compared to those without chemical fertilization. 
However, in June 2013, eight months after the 
second application, there were no differences in the 
concentrations of N in leaves in relation to 
fertilization, with an average value of 27.2 g kg-1 
(Figure 2B). 

Previous studies suggested that nitrogen 
fertilization, as well as other nutrient fertilization, 
should only be performed when the previous 
season's leaf analysis indicates that the nutrient was 
deficient (FERNÁNDEZ-ESCOBAR et al,. 2009, 
2012). Thus, the results obtained in this study 
indicated that, with the application of organomineral 
fertilization, the chemical N fertilization was 



1158 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

reduced in the two varieties. In addition, the foliar N 
increased in all treatments in the second year after 

fertilization (Figures 2A and 2B). 

 

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0 25 50 75 100

L
ev

el
s 

o
f 

 N
 (

g 
k

g-
1
)

Jul/12

Jun/13

Ŷ = 16.94

Ŷ = 23.96

(A) 'Ba rnea '

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L
ev

el
s 

o
f 

 N
 (

g 
k

g-
1
)

Jul/12

Jun/13

Ŷ = 15.830 + 0.070x  r² = 0.77

Ŷ = 27.24

(B) 'Gra ppolo 541'

1,0

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2,5

3,0

3,5

0 25 50 75 100

L
ev

el
s 

o
f 

 P
 (

g 
k

g-
1
)

Jul/12

Jun/13

Ŷ = 1.67

Ŷ = 2.93 - 0.015x  r² = 0.86

(C) 'Ba rnea '

1,0

1,5

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3,5

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L
ev

el
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o
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 P
 (

g 
k

g-
1
)

Jul/12

Jun/13

Ŷ = 2.13

Ŷ = 2.773 - 0.009x  r² = 0.81

(D) 'Gra ppolo 541'

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L
ev

el
s 

o
f 

 K
 (

g 
k

g 
-1

)

Chemica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 13.74

Ŷ = 14.50

(E) 'Ba rnea '

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0 25 50 75 100

L
ev

el
s 

o
f 

 K
 (

g 
k

g 
-1

)

Chem ica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 15.90

Ŷ = 15.89

(F) 'Gra ppolo 541'

 
Figure 2. Foliar levels of N (A and B), P (C and D) and K (E and F) in olive tree varieties ‘Barnea’ and 

‘Grappolo 541’ depending on the chemical fertilization in July 2012 and June 2013, UFVJM, 
Diamantina, MG, Brazil. 

 
Differences in the level of P in the leaves 

were observed in ‘Barnea’ in relation to fertilization 
only in the second year (June 2013), with a linear 
decrease from 51.2% in plants that received the 
100% level of the chemical fertilizer. The highest P 
levels were observed in plants that received no 
chemical fertilizer, while in July 2012, the P levels 
did not differ among chemical  fertilizations, with 
average values of 1.3 g kg-1 and 1.7 g kg-1, 
respectively (Figure 2C). In the leaves of variety 
‘Grappolo 541’, the levels of P were approximately 
2.1 g kg-1 in July 2012. However, in June 2013, the 
P levels decreased linearly from 2.8 g kg-1 to 1.9 g 
kg-1 with increasing chemical fertilization (Figure 
2D). 

The reduction in foliar P could be because 
nutrient was only applied during planting, as was 
the organomineral fertilizer, and as the plant grows, 
the nutrients are used for the growth and flowering 
process (RODRIGUES et al., 2012; EREL et al., 
2013). 

The levels of K in the leaves of the two 
varieties did not differ in relation to fertilization in 
all periods, showing that even with the reduction of 

chemical fertilizer, the level of this nutrient 
remained unchanged (Figures 2E and 2F). 

The results observed with respect to P and K 
showed that the organomineral fertilizer supplied 
these nutrients without the application of a chemical 
fertilizer. The foliar concentrations of nutrients were 
close to olive trees cultivated in Minas Gerais, 
Brazil, under a conventional fertilization system, 
with P from 1.2 g kg-1 to 5.2 g kg-1 and K from 15.0 
g kg-1 to 23.8 g kg-1 (MESQUITA et al., 2012). 

Thus, foliar analysis is the primary tool to 
assess the nutritional status of the plant, taking into 
account the relationship between nutrient 
concentrations and growth or productivity. 
Fernández-Escobar et al. (2009) found that, based 
on the annual application of N, P and K, along with 
spraying micronutrients, the traditional fertilization 
of olive groves practiced in the main cultivated 
regions increased the cost of fertilization without 
increased vegetative growth and production when 
compared with a fertilization program based on leaf 
analysis. 

There were no differences in the foliar 
levels of Ca, Mg and S for the two varieties of olive 



1159 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

tree among the fertilizers applied in both years 
(Figure 3). However, the Ca and Mg increased after 
the application of the organomineral fertilizer in the 
two varieties evaluated. In ‘Barnea’, which has 
rapid growth, Ca increased by 44.2% and Mg 
increased by 100.0% (Figures 3A and 3C). Increases 
of 60.0% in Ca and 80.0% in Mg (Figure 3B and 
3D) occurred in ‘Grappolo 541’. These increases 
occurred eight months after the application of the 

organomineral fertilizer in the second year (June 
2013) compared to the previous season of the 
application of treatments.  

This may have occurred because the 
organomineral fertilizer was composed of calcified 
seaweed of the genus Lithothamnium, which had the 
ability to adjust the pH of the soil, which improved 
the uptake of fertilizers and provided soluble Ca and 
Mg (MELO; FURTINI NETO, 2003). 

 

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 C
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 (g
 k

g-
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Jul/12

Jun/13

Ŷ = 15.75

Ŷ = 22.23

(A) 'Ba rnea '

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L
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 C
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 (g
 k

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Jul/12

Jun/13

Ŷ = 18.78

Ŷ = 23.70

(B) 'Gra ppolo 541'

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Ŷ = 0.41

Ŷ = 0.63

(C) 'Ba rnea '

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Ŷ = 0.63

Ŷ = 0.89

(D) 'Gra ppolo 541'

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 S
 (

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Chemica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 0.98

Ŷ = 1.91

(E) 'Ba rnea '

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Chemica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 1.29

Ŷ = 1.68

(F) 'Gra ppolo 541'

 
Figure 3. Foliar levels of Ca (A and B), Mg (C and D) and S (E and F) in olive tree varieties ‘Barnea’ and 

‘Grappolo 541’ depending on the chemical fertilization in July 2012 and June 2013, UFVJM, 
Diamantina, MG, Brazil. 

 
The micronutrients Fe and B decreased in 

both varieties after fertilization, and the lowest 
values were observed in the last assessment in June 
2013 (Figure 4). However, there were no differences 
between plants supplied with different fertilizations 
for B. The difference between seasons may be 
related to the start of production of the plants, since 
B is essential for the formation of flower buds and 
fruit development in olive trees (CARVALHO et 
al., 2013). 

There was an increase in the foliar 
concentrations of copper after fertilization in the 

variety ‘Barnea’, with values of 15.7 mg kg-1 before 
fertilization and in July 2012. Values increased 
linearly according to the increase in chemical 
fertilization, with a 260.0% increase in the plants 
that received 100% chemical fertilization and 
organomineral fertilizer (Figure 4C). The variety 
‘Grappolo 541’ had a similar behavior, and copper 
levels were approximately 11.6 mg kg-1 before 
fertilization and in July 2012. The values reached 
51.7 mg kg-1 in plants with 100% chemical 
fertilization, which corresponded to an increase of 
231.0% (Figure 4D).  

 



1160 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

0

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0 25 50 75 100

L
ev

el
s 

o
f 

 B
 (

m
g 

k
g-

1
)

Jul/12

Jun/13

Ŷ = 17.06

Ŷ = 8.45

(A) 'Ba rnea '

0

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0 25 50 75 100

L
ev

el
s 

o
f 

 B
 (

m
g 

k
g-

1
)

Jul/12

Jun/13

Ŷ = 15.03

Ŷ = 9.42

(B) 'Gra ppolo 541'

0

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0 25 50 75 100

L
ev

el
s 

o
f 

 C
u

 (
m

g 
k

g-
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Jul/12

Jun/13

Ŷ = 12.757 + 0.332x  r² = 0.87

Ŷ = 163.52

(C) 'Ba rnea '

0

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L
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o
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 C
u

 (
m

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g-
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Jul/12

Jun/13

Ŷ = 15.611 + 0.361x  r² = 0.81

Ŷ = 242.86 - 0.757x  r² = 0.91

(D) 'Gra ppolo 541'

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L
ev

el
s 

o
f 

 F
e 

(m
g 

k
g-

1
)

Chemica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 115.32 + 2.175x - 0.016x²  r² = 0.94

Ŷ = 93.40

(E) 'Ba rnea '

80

130

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230

280

0 25 50 75 100

L
ev

el
s 

o
f 

 F
e 

(m
g 

k
g-

1
)

Chem ica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 155.22

Ŷ = 99.10

(F) 'Gra ppolo 541'

 
Figure 4. Foliar levels of B (A and B), Cu (C and D) and Fe (E and F) in olive tree varieties ‘Barnea’ and 

‘Grappolo 541’ depending on the chemical fertilization in July 2012 and June 2013, UFVJM, 
Diamantina, MG, Brazil. 

 
Eight months after the second application 

(June 2013), the leaf levels of copper increased in 
both varieties, compared to the assessments at 
previous times. This result was likely due to a foliar 
spray with fungicide based on copper that was 
applied one month before the foliar sampling, which 
may have contributed to the elevation of the levels 
in plants of all treatments. 

The Mn levels in the variety ‘Barnea’ after 
fertilization did not differ between plants in 
different treatments, with values of 18.4 mg kg-1 in 
July 2012 and 14.7 mg kg-1 in June 2013 (Figure 
5A). The ‘Grappolo 541’ had a similar behavior, 
except in July 2013, when there was a linear 
increase of Mn foliar levels in accordance with the 
increase of chemical fertilizer. ‘Grappolo 541’ 
plants treated with 100% of the chemical fertilizer 
had 40.1 mg kg-1 of Mn (Figure 5B). 

The foliar concentrations of Zn in ‘Barnea’ 
linearly reduced with increasing chemical 
fertilization. Plants fertilized with 100% of the 
chemical fertilizer had levels of 12.3 mg kg-1 in July 

2012 and 14.1 mg kg-1 in June 2013, corresponding 
to decreases of 22.7% and 58.8%, respectively 
(Figure 5C). In the leaves of variety ‘Grappolo 541’, 
the Zn levels did not differ among the fertilizations 
in June 2013; all had values of 29.0 mg kg-1. There 
was a quadratic response in July 2012, with the 
highest value (24.4 mg kg-1) measured for the plants 
receiving an estimated 45% chemical fertilization 
(Figure 5D). 

 
 
 
 
 
 
 
 
 
 
 
 
 

 



1161 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

10

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0 25 50 75 100

L
ev

el
s 

o
f 

 Z
n

 (
m

g 
k

g-
1
)

Chem ica l fertiliza tion (%) 

Jul/12

Jun/13

Ŷ = 18.080 - 0.041x  r² = 0.71

Ŷ = 34.187 - 0.01x  r² = 0.85

(C) 'Ba rnea '

10

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0 25 50 75 100

L
ev

el
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o
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 Z
n

 (
m

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g-
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Chemica l fertiliza tion(%) 

Jul/12

Jun/13

Ŷ = 20.360 + 0.180x - 0.002x²  r² = 0.82

Ŷ = 28.98

(D) 'Gra ppolo 541'

10

20

30

40

50

0 25 50 75 100

L
ev

el
s 

o
f 

 M
n

 (
m

g 
k

g-
1
)

Jul/12

Jun/13

Ŷ = 18.37

Ŷ = 14.73

(A) 'Ba rnea '

10

20

30

40

50

0 25 50 75 100

L
ev

el
s 

o
f 

 M
n

 (
m

g 
k

g-
1
)

Jul/12

Jun/13

Ŷ = 24.16

Ŷ = 20.818 + 0.193x  r² = 0.65

(B) 'Gra ppolo 541'

 
Figure 5. Foliar levels of Mn (A and B) and Zn (C and D) in olive tree varieties ‘Barnea’ and ‘Grappolo 541’ 

depending on the chemical fertilization in July 2012 and June 2013, UFVJM, Diamantina, MG, 
Brazil. 

 
The lower levels of Mn and Zn after 

fertilization may be related to the use by plants, 
because the olive trees that received larger amounts 
of chemical fertilizer showed higher vegetative 
growth (Figure 6). Moreover, these micronutrients 
are involved in the reproductive process 
(CARVALHO et al., 2013). 

Taking into account the appropriate levels 
of foliar nutrients in the dry matter of olive trees in 
the main countries that grow them (FERNÁNDEZ-
ESCOBAR, 2008), it was found that a 50% 
reduction of chemical fertilization promoted levels 
of macronutrients and micronutrients, with the 
exception of Mg and B, that were considered 
adequate in all periods in the two varieties of olive 
tree. This may have occurred as a result of the 
benefits of the organomineral fertilizer in terms of 
providing nutrients (FERNANDES et al., 2007). 

It should be mentioned that there are no 
standards for the appropriate levels of nutrients in 
olive trees in Brazil, due to its recent cultivation. It 
is known that nutrient levels vary depending on 
plant phenology and that soil and climate factors 
influence their composition (FERNÁNDEZ-
ESCOBAR et al., 2009; MESQUITA et al., 2012) 
Thus, the patterns observed in other countries may 
not be consistent with the Brazilian reality, making 
it necessary to establish standards for olive trees 
grown in Brazilian conditions. 

In Minas Gerais, Brazil, a state that has seen 
an increase in olive cultivation, foliar nutrient levels 
in different varieties of olive trees in different stages 
of growth were established over years of analysis 

(MESQUITA et al., 2012). Comparing these data 
with the results observed in this study for all 
treatments applied, it was found that the foliar 
nutrients, P, K, Ca, S, B, Cu, Mn and Zn, were 
within the levels obtained for olive trees cultivated 
in a conventional system. N and Mg were also 
within these levels at the last evaluation, i.e., the 
levels increased after the second year with the use of 
the organomineral fertilizer without differences due 
to the reduction of the chemical fertilizer. 

Despite the reduction of chemical fertilizer, 
nutrient levels were not reduced in plants, 
highlighting that the organomineral fertilizer 
improved the efficiency of utilization by plants. This 
was possibly because the organomineral fertilizer 
contained sources of organic fertilizers, such as 
chicken manure and coffee husk, in addition to 
chemicals sources, such as magnesium silicate, 
calcium sulfate and partially soluble phosphorus, 
and calcified seaweed (Lithothamnium sp.). These 
sources provided nutrients and improved the plant 
utilization by reducing nutrient losses. 

The vegetative growth of the olive trees 
increased by 425.0% in increment in height only in 
the variety ‘Barnea’, with 100% application of 
chemical fertilizer compared to plants that received 
no fertilizer in July 2012 (Figure 6A). However, in 
June 2013, the variety ‘Barnea’ showed the greatest 
height with 68.9% of the recommended chemical 
fertilization and ‘Grappolo 541’ with 64.6% 
fertilization (Figures 6A and 6B). 

 



1162 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

0

30

60

90

120

150

0 25 50 75 100

In
cr

em
en

t i
n

 h
ei

gh
t 

 (
cm

)

Jul/12

Jun/13

Ŷ = 6.8 + 0.289x r² = 0.71

(A) 'Ba rnea '

Ŷ = 39.4 + 2.329x - 0.01698x²
r² = 0.74

0

30

60

90

120

150

0 25 50 75 100

In
cr

em
en

t i
n

 h
ei

gh
t 

(c
m

)

Jul/12

Jun/13

Ŷ = 20.71

(B) 'Gra ppolo 541'

Ŷ = 10.6 + 1.680x - 0.013x²  
r² = 0.99

0

5

10

15

20

25

30

0 25 50 75 100

In
cr

em
en

t i
n

 s
te

m
 d

ia
m

a
te

r  
(m

m
)

Jul/12

Jun/13

Ŷ = 2.0 + 0.058x r² = 0.90

(C) 'Ba rnea '

Ŷ = 9.4 + 0.197x r² = 0.86

0

5

10

15

20

25

30

0 25 50 75 100

In
cr

em
en

t i
n

 s
te

m
 d

ia
m

et
er

 (m
m

) Jul/12

Jun/13

Ŷ = 3.32

(D) 'Gra ppolo 541'

Ŷ = 6.1 + 0.112x r² = 0.79

0

3

6

9

12

15

0 25 50 75 100

P
ro

du
ct

io
n 

su
rf

ac
e 

(m
²)

Chemical fertilization (%)  

Jul/12

Jun/13

Ŷ = 6.0 + 0.033x  r² = 0.73 

Ŷ = 6.1 +  0.083x  r² = 0.93

(E) 'Ba rnea '

0

3

6

9

12

15

0 25 50 75 100

P
ro

du
ct

io
n 

su
rf

ce
 (

m
²)

Chemical fertilization (%)  

Jul/12

Jun/13

Ŷ = 3.3 + 0.018x  r² = 0.92

Ŷ = 4.3 + 0.091x - 0.00066x²  r² = 0.94

(F) 'Gra ppolo 541'

 
Figure 6. Increment in height (A and B), increment in stem diameter (C and D) and production surface (E and 

F) in olive tree varieties ‘Barnea’ and ‘Grappolo 541’ depending on the chemical fertilization in July 
2012 and June 2013, UFVJM, Diamantina, MG, Brazil. 

 
In the variety ‘Barnea’, the stem diameter 

increased by 285.4% and 209.7% with the 
application of 100% chemical fertilizer in July 2012 
and June 2013, respectively, compared to plants 
without chemical fertilization (Figure 6C). In 
‘Grappolo 541’, there was an increase of 182.2% in 
June 2013, with 100% chemical fertilization 
compared to plants fertilized only with the 
organomineral fertilizer (Figure 6D). 

The greater vegetative growth of the trees 
depending on the fertilization of plants is mainly 
related to N, which is important for the metabolism 
of plant growth and can be stored in organs when it 
is not used (Bustan et al. 2013). N is also important 
to the growth habit of varietys, which justifies the 
foliar N after fertilization in the variety ‘Grappolo 
541’ in July 2012 (Figure 2A). Thus, comparing the 
vegetative behavior, it is possible to relate the 
highest concentration of N in ‘Grappolo 541’, which 
received 100% of the recommended chemical 
fertilizer, to the slower growth of these plants. 

‘Barnea’ had a linear increase in the 
production surface as a function of chemical 
fertilizer with growth of 55.3% in July 2012 and 
137.0% in June 2013, compared to plants without 
chemical fertilization (Figure 6E). In ‘Grappolo 

541’, the increase was 53.8% in July 2012 and 
48.53% in June 2013, at an estimated 45.5% of 
chemical fertilization compared to those fertilized 
with only the organomineral fertilizer (Figure 6F). 

The difference in the vegetative growth of 
‘Grappolo 541’ in relation to fertilization may be 
related to the growth habit and nutrient utilization. 
Higher nutrient levels observed in this variety may 
be related to this habit of slower growth, a behavior 
already reported for the variety ‘Nabali’ compared 
with the olive tree varieties ‘Grossa d’ España’, 
‘Nabali Mohassan’ and ‘Manzanillo’ (FREIHAT; 
MASA’DEH, 2006). 

In addition to the nutritional factors, the 
vegetative growth of the olive tree is very 
influenced by environmental factors because, 
according to Orlandi et al. (2013), a short 
photoperiod completely limits the development of 
the crown of the olive tree, while a long photoperiod 
promotes the acceleration of this development. The 
high temperatures combined with high rainfall 
temperatures, as those recorded in this study during 
the summer (Figure 1), also favored the vegetative 
growth. 

It is necessary to consider that the plants 
were established in a newly prepared area and, after 



1163 
Effect of reducing chemical fertilizer…  MOREIRA, R. A. et al. 

Biosci. J., Uberlândia, v. 33, n. 5, p. 1155-1165, Sept./Oct. 2017 

the application of the organomineral fertilizer, the 
soil chemical properties improved. Perennial species 
fertilizations should be thoughtful, observing the use 
of nutrients by the varieties during vegetative and 
reproductive growth, and aiming to promote the 
development and productivity of the trees. The 
excessive application of chemical fertilizer without 
consideration of the phenological variability of 
plants and features related to the area of cultivation 
leads to increased production costs and 
environmental risks (Boussadia et al. 2010). 

 

CONCLUSIONS 
 
The nutritional behavior of olive tree 

varieties ‘Barnea’ and ‘Grappolo 541’ was 
unchanged with a 50% reduction of chemical 
fertilizer combined with the application of an 
organomineral fertilizer. The variety ‘Barnea’, with 
the habit of rapid growth, had lower foliar nutrient 
concentrations. Reduction of the chemical fertilizer 
to 64.5%, with the application of the organomineral 
fertilizer, had no effect on vegetative growth of the 
olive tree variety ‘Grappolo 541’. 

 
 
RESUMO: A pesquisa foi realizada com o objetivo de avaliar o comportamento nutricional e o crescimento 

vegetativo de duas variedades de oliveira, com a redução da adubação química, pela aplicação do fertilizante 
organomineral. Foram utilizadas duas variedades de oliveira, ‘Barnea’ e ‘Grappolo 541’, de três anos de idade, 
implantadas no campo, em solo classificado como Neossolo Quartzarênico. Utilizou-se o esquema de parcela subdividida, 
na parcela o fatorial 4 x 2, sendo quatro adubações e duas variedades e, na subparcela, os anos de avaliação. As adubações 
constituíram-se 100%, 75%, 50% e 0% da adubação química recomendada para a oliveira, distribuídas em blocos 
casualizados, com três blocos e três plantas por parcela. Em todas as plantas foi feita a aplicação do fertilizante 
organomineral. As amostras foliares e a avaliação do crescimento vegetativo foram realizadas em julho de 2012 e julho de 
2013. O comportamento nutricional das variedades de oliveira ‘Barnea’ e ‘Grappolo 541’ não foi alterado com a redução 
de 50% da adubação química e a aplicação de fertilizante organomineral. ‘Barnea’, com hábito de crescimento rápido, 
apresenta menores teores foliares de nutrientes. A redução da adubação química em 64,5%, com a aplicação de fertilizante 
organomineral, não interferiu no crescimento vegetativo da ‘Grappolo 541’. 

 
PALAVRAS-CHAVE: Olea europaea. nutrição mineral. ‘Barnea’. ‘Grappolo 541’. 

 
 
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