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796 
Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 3, p. 796-805, May/June 2019 
http://dx.doi.org/10.14393/BJ-v35n3a2019-41956 

GREEN ONION PRODUCTION UNDER STRATEGIES OF REPLACEMENT 
AND FREQUENCIES OF CIRCULATION OF BRACKISH NUTRITIVE 

SOLUTIONS 
 

PRODUÇÃO DE CEBOLINHA SOB ESTRATÉGIAS DE REPOSIÇÃO E 
FREQUÊNCIAS DE CIRCULAÇÃO DE SOLUÇÕES NUTRITIVAS SALOBRAS 

 
Fernando José da SILVA JÚNIOR1, José Amilton SANTOS JÚNIOR2, Nildo da Silva DIAS3, 

Hans Raj GHEYI4, Rene Chipana RIVERA5, Gerônimo Ferreira da SILVA2,  
Cleyton dos Santos FERNANDES6 

1. Mestre em Engenharia Agrícola pela Universidade Federal Rural de Pernambuco, Recife, PE, Brasil; 2. Professor, Universidade 
Federal Rural de Pernambuco, Recife, PE, Brasil. eng.amiltonjr@hotmail.com; 3. Professor, Universidade Federal Rural do Semi-Árido, 

Mossoró, RN, Brasil; 4. Professor visitante, Universidade Federal do Recôncavo da Bahia, Cruz das Almas, BA, Brasil; 5. Professor, 
Universidad Mayor de San Andrés, La Paz, Bolívia; 6. Mestrando em Manejo de Solo e Água, Universidade Federal Rural do Semi-

Árido, Mossoró, RN, Brasil. 
 

ABSTRACT: The cultivation of vegetables in semi-arid regions, especially in the context of the use of 
brackish water, has been made possible by the use of the hydroponics technique. Thus, two experiments were 
carried out between December 2016 and January 2017 in a protected environment at the Federal Rural 
University of Pernambuco (UFRPE), Recife – PE, Brazil (8° 1”7” South latitude and 34° 56” 53” West 
longitude, and average altitude of 6.5 m), aiming at evaluating the production of green onion (cv. “Todo dia” 
Evergreen - Nebuka) in plants exposed to brackish nutrient solution (1.5, 3.0, 4.5, 6.0, 7.5 and 9.0 dS m-1), 
applied at two frequencies of circulation (twice a day - at 8 and 16 hours, and three times per day - at 8, 12 and 
16 hours) in low-cost hydroponics system. In Experiment I, the nutrient solution evapotranspirated by the 
plants was replaced with the respective brackish water used in its preparation, and in Experiment II with 
UFRPE supply water (0.12 dS m-1). In both cases, a completely randomized experimental design was used, in a 
6 x 2 factorial scheme, with five replications. It was concluded that under replacement with brackish water, the 
increase in the frequency of circulation attenuated the losses imposed by the salinity to the biometric variables 
and of the production of fresh and dry phytomass of the plants; the water supply replenishment had a greater 
mitigating role in relation to the damage caused by the salinity with the increase of the electrical conductivity of 
the nutrient solution. 

 
KEYWORDS: Allium fistulosum L. Cultivation without soil. Salinity. 

 
INTRODUCTION 

 
Green onion (Allium fistulosum L.) is one of 

the most popular condiment vegetables in human 
diet (CARDOSO; BERNI, 2012; ARAUJO et al., 
2016). The most traditional cultivar is “Todo dia” 
Evergreen - Nebuka, widely used in the North and 
Northeast of Brazil; with leaves of light green color, 
it is characterized by the intense tillering forming 
clumps, so that its harvest occurs through cuts 
between 55 and 80 days after planting, when the 
leaves reach from 0.20 to 0.40 m height, and their 
sprouts can be harvested for two to three years 
(FILGUEIRA, 2008). However, when cultivated in 
a traditional manner, plant exposure to abiotic 
factors, such as salinity, may reduce the quantity 
and quality of the harvested product (ARAUJO et 
al., 2016). 

In semi-arid environments, given their 
specific hydrogeological conditions, salinity 

promotes modifications in metabolic activities and 
affects cell elongation, reducing plant growth and in 
extreme cases can lead to death (SAIRAM; TYAGI, 
2004), especially due to the osmotic levels, which 
coupled with the matrix potential, requires greater 
energy for the absorption of water and nutrients by 
the plant. 

However, under hydroponic conditions, the 
water potential depends on the osmotic potential 
and, since there is no soil, the matrix potential is 
practically null (SOARES FILHO et al., 2016). 
Thus, it is necessary to adapt this technique to the 
needs and reality of small farmers, that is, a low-
cost hydroponic system (SANTOS JÚNIOR et al., 
2016) is an alternative for the production of 
vegetables in regions with water limitations, where 
the use of brackish water in agriculture is essential 
(SANTOS et al., 2010; SOARES et al., 2010; 
JESUS et al., 2015). 

Received: 23/04/18 
Accepted: 05/12/18 



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Nevertheless, the adoption of strategies for 
the use of brackish water in hydroponic crops can 
further minimize the damage caused and potentiate 
the production of crops, especially vegetables 
(SOARES et al., 2010). Up to the present, 
significant results have been reported in vegetable 
cultivation using techniques such as nutrient 
solution preparation with brackish water and 
evapotranspiration replacement with regular supply 
water, due to the successive reduction of the 
concentration of salts at every replacement (ALVES 
et al., 2011; SOARES et al., 2010) and the use of 
higher frequencies of nutrient solution circulation 
due to the minimization of the variation in salt 
concentration and greater oxygenation of the 
solution (SOARES et al., 2016). 

Therefore, the production of scallion (cv. 
“Todo dia” Evergreen - Nebuka) was evaluated in 
plants exposed to strategies of replacement and 
frequencies of circulation of brackish nutrient 
solutions. 
 
MATERIAL AND METHODS 
 

The experiments were carried out in a 
greenhouse at the Federal Rural University of 
Pernambuco, Recife - PE, Brazil (8° 1”7” South 
latitude and 34° 56” 53” West longitude, and 
average altitude of 6.5 m) between December 2016 
and May 2017. In this period, the average maximum 
and minimum temperatures were 37.4 ºC and 32.2 
ºC, and the average maximum and minimum values 
of relative humidity were 61.4% and 44.5 %. 

The experimental design was completely 
randomized, analyzed in a 6 x 2 factorial scheme, 
with five replications. The treatments consisted of 
six salinity levels of the nutrient solution (1.5, 3.0, 
4.5, 6.0, 7.5 and 9.0 dS m-1) applied at two 
frequencies of circulation (twice a day - at 8 and 16 
hours, and three times per day - at 8, 12 and 16 
hours). In the first experiment, the volume of 
nutrient solution evapotranspirated by plants was 
done with the respective brackish water used in its 
preparation and, in the second experiment, with 
water from the supply system (0.12 dS m-1). 

The low-cost hydroponic system was 
composed of twelve PVC tubes with diameter of 
100 mm and six meters long, arranged in level, with 
joints at the ends and, in one of them, a tap was 
installed to induce a level of four centimeters of 
solution along the tube. Cultivation was done in 180 
mL disposable cups, filled with coconut fiber and 
perforated in the final third of the sides and bottom, 
which were placed in 60-mm-diameter holes, spaced 
by 14 cm. Six wooden supports were used with a 

tube fixed at each end; these supports were reduced 
every 0.20 m, the base support being 1.40 m and the 
top supporting 0.40 m (SANTOS JÚNIOR et al., 
2016). 

The evaluated culture was scallion (cv. 
“Todo dia” Evergreen - Nebuka), the sowing done 
directly in the disposable cups filled with coconut 
fiber; after sowing, these were inserted into the final 
tubes and received the solution of Furlani et al. 
(1999) up to 24 days. At 25 days after germination 
(DAG) the plants received saline treatments. 

In relation to the preparation of the nutrient 
solution, 90 L of supply water (EC 0.12 dS m-1) 
were placed in twelve different containers, 
dissolving the amount of fertilizer recommended by 
Furlani et al. (1999). Subsequently, NaCl was added 
in adequate amounts, estimated on the basis of an 
empirical relationship proposed by Richards (1954), 
and the required levels of nutrient solution salinity 
were obtained. 

Nutrient solution management was based on 
the recycling of water and nutrients (closed system), 
and evapotranspiration was replaced weekly 
according to each treatment as well as the frequency 
of circulation. However, at each circulation event, 
40 L of nutrient solution was applied slowly, in 
order to homogenize and aerate the solution. In this 
process, as the tubes were level, excess solution 
flowed through the tap, set to keep the nutrient 
solution level inside the tube, and then returned to 
the reservoir. The parameters electrical conductivity 
(ECns) and pH of the nutrient solution (pHns) were 
monitored daily, making it unnecessary to make 
adjustments for the small variations. 

The evaluated crop was green onion (cv. 
“Todo dia” Evergreen - Nebuka), which was sown 
directly in the disposable cups filled with coconut 
fiber; after sowing, these were inserted into the final 
tubes and received the solution of Furlani et al. 
(1999) until 24 days. At 25 days after germination 
(DAG), plants received saline treatments. 

Production variables were evaluated at the 
end of the crop cycle (65 DAG), namely: total fresh 
phytomass, shoot fresh phytomass and root fresh 
phytomass per plant, that is, the respective fresh 
masses were collected and immediately weighed on 
a precision scale (0.01 g). Then they were dried in a 
forced ventilation oven at 65 ºC until reaching 
constant weight, to obtain total dry matter, shoot dry 
matter and root dry matter. With these variables, the 
percentages of total dry matter, shoot dry matter and 
root dry matter were calculated. Root length was 
measured from the stem insertion point to the root 
tip and plant height, from pseudostem base to the 
top of the last leaf. 



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The results were submitted to analysis of 
variance by F test. When a significant effect of the 
interaction between treatments was observed, the 
discussion was prioritized. In the other cases, 
quantitative factors were compared by regression 
analysis and qualitative factors by Tukey test at 0.05 
probability level. All analyses were performed using 
statistical software (FERREIRA et al., 2011). 

 
RESULTS AND DISCUSSION 
 

When the evapotranspiration was replaced 
with brackish water, a tendency of accumulation of 
salts in the solution was observed, with a maximum 
increase of ECns, compared to the initial levels, 
observed under 3.0 dS m-1 (33%) and 4.5 dS m-1 
(31%); at fourteen days after the start of saline 
treatments, in contrast, a decrease in pHns was 
registered, with the most significant reductions at 
ECns levels of 1.5 dS m-1 (14%) and 6.0 dS m-1 
(11%) from 39 days after planting (DAP). 

When the replacement was performed with 
supply water, the trend was the reduction of ECns 
and, in treatments with 6.0 dS m-1 (18%) and 9.0 dS 
m-1 (16%), a greater percentage decrease was 

observed after 39 (DAP). Regarding pHns, a 
downward trend was also observed, with a 
maximum reduction recorded at the ECns level of 
1.5 dS m-1 (14%) from 39 (DAP). 

Thus, the oscillations of ECns and pHns 
when evapotranspiration was replaced with supply 
water were within the range recommended by 
Furlani et al. (1999), that is, a maximum ECns 
variation of 25% and pH between 5.5 and 6.5. In the 
case of the use of brackish water, the variation in 
ECns exceeded the maximum recommended 
variation due to the contributions of NaCl and was 
observed after fourteen days of adding NaCl to the 
nutrient solution. However, the pHns remained 
within the proposed range. 

According to the results of the analysis of 
variance, total fresh phytomass (TFP), shoot fresh 
phytomass (SFP) and root fresh phytomass (RFP), 
as well as total dry matter (TDM), shoot dry matter 
(SDM) and root dry matter (RDM) were 
significantly influenced by the electrical 
conductivity (p <0.01) and the circulation frequency 
of the nutrient solution, as well as by the interaction 
between the treatments, under evapotranspiration 
replacement with brackish water or supply water. 

 
Table 1. Summary of the F test for the fresh and dry total biomass of shoots and roots of  green onion (cv. 

“Todo dia” Evergreen - Nebuka) as a function of the salinity levels and frequency of circulation of the 
nutrient solution considering strategies of replacement of the evapotranspired depth with brackish 
water (Experiment I) and with supply water (Experiment II). 

Source of 
variation 

DF 
F Test 
TFP SFP RFP TDM SDM RDM 

BW SW BW SW BW SW BW SW BW SW BW SW 
Salinity (S) 5 ** ** ** ** ** ** ** ** ** ** ** ** 

Quadratic 
regression 

1 
** ** ns ns ** ** ns ** ns ns ns ** 

Frequency (F) 1 ** ** ** ** ** ** ** ** ** ** ** ** 

Interaction S x F 5 ** ** ** ** ** ** ** ** ** ** ** ** 

Error 48 48 48 48 48 48 48 48 48 48 48 48 48 
CV % 9.51 3.59 11.70 3.77 13.29 10.73 10.36 6.14 12.77 6.96 9.29 13.25 

DF = degrees of freedom; CV = coefficient of variation; ** = significant at 0.01 probability level; * = significant at 0.05 probability 
level; ns = not significant. TFP, SFP and RFP = total fresh phytomass, shoot fresh phytomass and root fresh phytomass; TDM, SDM and 
RDM = total dry matter, shoot dry matter and root dry matter. BW = replacement with brackish water and SW = replacement with 
supply water. 
 

The TFP of plants under replacement with 
brackish water (Figure 1A) was linearly reduced at 
rates of 0.1512 and 0.18181 g per dS m-1 increased 
in ECns. On the other hand, when comparing the 
results of the plants under 1.7 and 9.0 dS m-1 losses 
were estimated to be 45.59% and 51.23%, under 
two and three circulations per day, respectively, and 
frequency was not a mitigating factor (p> 0.05), 
except for 3.0 dS m-1. 

The losses were lower (45.17% and 
39.57%) when supply water was used (Figure 1B) in 
the replacement, with estimated decreases in the 
TFP of 1.6477 and 1.5236 g, per unit increase of 
ECns, under two and three circulations per day, 
respectively. In this case, from 3.0 dS m-1 there were 
significant gains in the TFP when three circulations 
were used per day, emphasizing its mitigating role. 
Other vegetables under salt stress also show a 
reduction in TFP, as noted by Oliveira et al. (2013) 



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who subjected arugula plants to ECns levels (1.2, 
2.2, 3.2, 4.2 and 5.2 dS m-1) and observed a 

reduction in TFP in response to the increase in 
ECns. 

(A) (B) 

  
(C) (D) 

  
(E) (F) 

  
(G) (H) 

  
(I) (J) 

  
(K) (L) 

  
Figure 1. Results for green onion plants (cv. “Todo dia” Evergreen - Nebuka) under salinity and circulation 

frequencies of the nutrient solution replaced with brackish water and supply water. Follow-up test of 
the interaction between treatments for total fresh phytomass – TFP (A and B), shoot fresh 
phytomass – SFP (C and D), root fresh phytomass – RFP (E and F), total dry matter – TDM (G and 
H), shoot dry matter – SDM (I and J) and root dry matter – RDM (K and L). Equal letters for each 
salinity level do not differ at 0.05 probability level. 



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After analysis of the results with respect to 
SFP, it was observed that under replacement with 
brackish water (Figure 1C), the estimated results 
varied as a function of the frequency of nutrient 
solution circulation, with decreases of 2.721 and 
2.0907 g per dS m-1 increased in ECns, and when 
plants were compared under 1.5 and 9.0 dS m-1, the 
difference was up to 87.84% and 81.09% for two 
and three circulations per day, respectively. 
Similarly, under replacement with SW (Figure 1D), 
the decreases per unit increase in ECns were 
estimated at 0.8469 and 0.7529 g, as well as at 
25.4% and 30.60% compared to the SFP of plants 
under 1.5 and 9.0 dS m-1, for two and three 
circulations per day, respectively. The reduction in 
SFP under salinity conditions has already been 
observed for several types of vegetables such as 
coriander (SILVA et al., 2014), lettuce (OLIVEIRA 
et al., 2011), and arugula (JESUS et al. 2015). In 
general, the authors attribute this reduction to the 
increase in energy demand for water and nutrient 
absorption under salinity conditions (TAIZ; 
ZEIGER, 2013). 

With respect to the root, under replacement 
with brackish water, RFP decreased at rates of 
0.6101 and 0.828 g per dS m-1 increased in ECns, 
with estimated losses (in the interval between 1.5 
and 9.0 dS m-1) of 81.57% and 88.67%, under two 
and three circulations per day, respectively (Figure 
1E). Under replacement with supply water, the 
losses per unit increase in ECns were estimated at 
0.6138 and 0.6704 g and the total losses at 66.52% 
and 61.96% for two and three circulations of the 
solution per day, respectively (Figure 1F). 

The estimated losses for shoot fresh 
phytomass were more expressive than those 
observed for the root, especially under replacement 
with brackish water. It is worth mentioning, 
however, the attenuating role of increasing 
circulation frequency for three circulations per day 
in favor of fresh phytomass, except under 
replacement with brackish water at levels above 7.5 
dS m-1. In all other cases, there was a reduction in 
the losses of the shoot in detriment of the root. The 
increase in the number of circulations per day 
probably reduced the concentration of the solution 
remaining inside the tube by frequent 
homogenization with the tank solution, in addition 
to increasing the volume supplied and oxygenation. 

After the analysis of the interaction between 
treatments for TDM, there were decreases of 0.1589 
and 0.2158 g per unit increase in ECns, as well as 
estimated losses of 71.12% and 73.69% within the 
proposed salinity range, under two and three 
circulations per day, respectively, in plants under 

replacement with brackish water (Figure 1G). 
Otherwise, when evapotranspiration was replaced 
with supply water, the estimated decreases per unit 
increment in ECns were 0.1864 and 0.1788 g, with 
losses of 63.51% and 56.55% within the studied 
range of salinity, for two and three circulations per 
day, respectively (Figure 1H). The increase in the 
frequency of circulation was important up to the 
level of 6.0 dS m-1 when the replacement was 
performed with brackish water, while no differences 
were found (p>0.05) from 3.0 dS m-1 when supply 
water was used. 

The SDM losses per unit increase in ECns 
(0.1351 g and 0.1746 g), as well as the difference in 
the shoot dry matter of the plants under 1.5 and 9.0 
dS m-1 (72.03% and 79.64%) were affected by the 
circulation frequencies of two and three times per 
day, respectively, under replacement with brackish 
water (Figure 1I). The response was similar to that 
of SW (Figure 1J), but with less intensity, so that the 
losses per unit increase in salinity (0.1283 g and 
0.1002 g) and those estimated within the salinity 
range (59.49% and 44.06%) varied for the 
frequencies of two and three times per day, 
respectively; in this case, from 6.0 dS m-1, influence 
(p<0.05) was observed when the circulation 
frequency increased. The results presented 
corroborate the data found by Zanella et al. (2008), 
submitting lettuce plants (cv. Regina 2000 and Lucy 
Brown) in NFT hydroponic system to 15 minutes of 
circulation at intervals of 5, 15, and 30 minutes. 
These authors found that the highest accumulation 
of shoot dry matter occurred when a greater number 
of irrigation events were used per day. 

In relation to the RDM, under replacement 
with brackish water (Figure 1K), the estimated 
losses per unit increment in ECns were 0.0212 and 
0.0583 g, with total decreases of 47.26% and 
75.07%, for circulation of two and three times per 
day, respectively. When SW was used (Figure 1L), 
at the estimated reductions were 0.0606 and 0.0787 
g per dS m-1, with losses of 80.10% and 84.50% 
within the salinity range, for two and three 
circulations of the solution per day, respectively. 
From 7.5 dS m-1, for both replacement strategies, no 
significant increase in the circulation frequency was 
observed (p>0.05) under RDM. However, for ECns 
lower than this value, the influence of this treatment 
was effective (p <0.05).The results differ from those 
found by Silva et al. (2016),  who subjected 
coriander plants to two types of brackish water (EC 
= 0.32 dS m-1 and EC = 4.91 dS m-1) with four 
recirculation frequencies of the nutrient solution 
(0.25; 2; 4 and 8 h), and observed that accumulation 
of root dry matter occurred independently of the 



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recirculation frequencies of the nutrient solution, at 
the same level. 

In a general analysis of dry matter, it is 
worth highlighting the importance of increasing the 
frequency of circulation under replacement with 
brackish water and emphasizing that, under 
replacement with SW, the use of three circulations 
per day started to have a greater mitigating role with 
the increase of the ECns, due to the large number of 
nutrient solution circulation events, minimizing the 
effect of salinity on plants. Munns and Tester (2008) 
associate the reduction of dry phytomass to the 
osmotic effect of salinity, the toxic effect of Na+ and 

Cl- and the ionic imbalance caused by the excess of 
these ions. 

Plants under increasing ECns exhibited 
significant variation (p <0.05) in %TDM, %SDM, 
%RDM, RL and PHG, for both nutrient solution 
replacement strategies. In relation to the frequency 
of circulation, under replacement with brackish 
water, there was significance (p <0.05) for %TDM, 
%SDM, RL and PHG, and under replacement with 
supply water, for %SDM and RL. The interaction 
between treatments influenced (p <0.05) the results 
of RL and PHG in both experiments (Table 2). 

 
Table 2. F Test for the percentage of total dry matter (%TDM), shoot dry matter (%SDM) and root dry matter 

(%RDM), for root length (RL) and for plant height (PHG) of green onion (cv. “Todo dia” Evergreen - 
Nebuka) as a function of the salinity levels and frequency of application of the nutrient solution in the 
strategies of replacement with the respective brackish water and supply water (SW). 

Source of 
variation 

DF 
 F Test 
%TDM %SDM %RDM RL PHG 
BW SW BW SW BW SW BW SW BW SW 

Salinity (S) 5 ** ** ** ** ** ** ** ** ** ** 
Quadratic 
regression 

1 
ns ns ns ns ns ** ** ** ns ** 

Frequency (F) 1 ** ns ** ** ns ns ** ** ** ns 
Interaction SxF 5 ns ns ns ns ns ns ** ** ** ** 
Error 48 48 48 48 48 48 48 48 48 48 48 
CV % 10.43 9.99 10.16 10.47 8.71 7.73 8.56 6.14 4.71 10.65 

DF = degree of freedom; CV = coefficient of variation; ** = significant at 0.01 probability level; ns = not significant. BW = replacement 
with brackish water and SW = replacement with supply water. 
 

After analysis of %TDM, it was found that 
under replacement with brackish water and SW the 
reductions were estimated at 0.0802 and 0.3472% 
per dS m-1 increased in ECns (Figure 2A). In 
relative terms, it was evident that the reduction in 
%SDM had a smaller participation in the total 
losses, under both replacement strategies, brackish 
water (0.2333%) and SW (0.3042%) for every 
increase in dS m-1 (Figure 2B), in comparison to the 
%RDM, whose estimates of the reduction per unit 
increase in ECns were 0.2429 and 0.4042% for 
brackish water and SW, respectively (Figure 2C). It 
is worth mentioning, however, that the frequency of 
circulation of the nutrient solution failed to attenuate 
the deleterious effect of salinity on the root, an 
organ directly exposed to stress. 

In spite of the fact that 40% of the dry 
matter is composed of carbon (LAMBERS et al., 
2008) and the deleterious impact of the ECns on the 
photosynthetically active area of the plant, a process 
responsible for its fixation, the replacement strategy 
with supply water and the increase in nutrient 
solution circulation frequency mitigated the effect of 
salts on dry matter in all parts of the plant. The 

higher root losses may be associated to the fact that, 
since this organ is directly exposed to salinity, it 
must perform osmotic adjustment (GUERZONI et 
al., 2014), thus reducing the rate of dry matter 
accumulation and also nutrient uptake, which are 
essential for plant development (DEINLEIN et al., 
2014, RODRIGUES et al., 2014). 

For RL, under replacement with brackish 
water, as a function of nutrient solution salinity 
within the circulation frequencies of this solution 
(Figure 2D), a linear reduction occurred at both 
frequencies, decreasing by 0.8981 and 0.8278 cm 
per dS m-1 increased in ECns, with losses estimated 
at 43.36% and 38.90%. On the other hand, when the 
evapotranspiration was replaced with SW (Figure 
2E), there were reductions of 0.9196 and 0.923 cm, 
with estimated losses of 43.27% and 42.06% per 
unit increase in salinity with two and three solution 
circulations per day, respectively. This reduction in 
the roots is due to the direct contact and absorption 
of the saline solution, and consequently changes in 
the water relations of the cell, in which it prevents 
water absorption by the plant (WILLADINO et al., 
2010). 



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(A) (B) 

  
(C) (D) 

  
(E) (F) 

  
(G) 

 
Figure 2. Results for green onion (cv. “Todo dia” Evergreen - Nebuka) due to strategies of brackish water use 

in hydroponic system. Percentage of total dry matter - %TDM (A), shoot dry matter - %SDM (B) and 
root dry matter – RDM (C) under replacement with brackish water and supply water. Follow-up test 
of the interaction between treatments for root length - RL (D and E) and plant height - PHG (F and 
G). Equal letters for each salinity level do not differ at 0.05 probability level. 

 
In the case of replacement with brackish 

water, it was observed that the height of the plants 
was linearly reduced, having estimated decreases of 
1.801 and 2.2886 cm per dS m-1 increased, with 
losses of 44.54% and 49.71% within the salinity 
range studied, under two and three circulations per 
day, respectively (Figure 2F). Likewise, when the 
evapotranspired depth was replaced with supply 
water (Figure 2G), reductions of 1.8401 and 2.0272 

cm were observed per unit increase in ECns, with 
losses within the salinity range estimated at 42.65% 
and 41.41% under two and three circulations per 
day, respectively. Similar results were found by 
Silva et al. (2014) in studies with the green onion 
cv. “Todo dia”. These authors observed that, at 30 
days after transplanting, plants subjected to saline 
level of 0.7 dS m-1 began to decrease by 7.0% per 



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unit increase in salinity, and the difference between 
the highest and the lowest saline level was 19%. 
 
CONCLUSIONS 
 

The use of three circulations of the solution 
per day attenuated the losses of the biometric 
variables and the production of fresh and dry 
phytomass of the plants under replacement with 
brackish water, and when supply water was adopted, 
it began to have a greater mitigating role with the 
increase in nutrient solution salinity. 

The increase in nutrient solution salinity 
reduced the percentage of total dry matter, shoot dry 

matter and root dry matter; however, increasing the 
frequency of circulation of the nutrient solution did 
not mitigate the deleterious effect of salinity on the 
percentage of dry matter of the root, an organ 
directly exposed to saline stress. 

 
ACKNOWLEDGMENT 
 

The authors would like to thank the 
National Council for Scientific and Technological 
Development (CNPq) for the financing of the 
project. 

 
 

RESUMO: O cultivo de hortaliças em regiões semiáridas, especialmente no contexto de uso de águas 
salobras, tem sido viabilizado pelo uso da técnica da hidroponia. Diante disto, entre janeiro de 2016 e abril de 
2017, foram conduzidos dois experimentos em ambiente protegido na Universidade Federal Rural de 
Pernambuco (UFRPE), Recife, PE (8° 1”7” Sul e 34° 56” 53” Oeste, altitude média de 6,5 m), objetivando-se 
avaliar a produção da cebolinha (cv. Todo ano Evergreen - Nebuka) em plantas expostas a soluções nutritivas 
salobras (1,5; 3,0; 4,5; 6,0; 7,5 e 9,0 dS m-1) aplicadas em duas frequências de circulação (duas vezes ao dia - às 
8 e às 16 horas; e três vezes ao dia - às 8, 12 e 16 horas). Em ambos os casos, utilizou-se um delineamento 
experimental inteiramente casualizado, em esquema fatorial 6 x 2, com cinco repetições. No Experimento I, a 
lâmina de solução nutritiva evapotranspirada pelas plantas foi reposta com a respectiva água salobra utilizada 
no seu preparo e, no Experimento II, com água de abastecimento da UFRPE (0,12 dS m-1). Concluiu-se que sob 
reposição com água salobra, o aumento da frequência de circulação atenuou as perdas impostas pela salinidade 
às variáveis biométricas e de produção de fitomassa fresca e seca das plantas; a reposição com água de 
abastecimento passou a ter maior papel mitigador em relação ao dano causado pela salinidade com o aumento 
da condutividade elétrica da solução nutritiva. 

 
PALAVRAS-CHAVES: Allium fistulosum L. Cultivo sem solo. Salinidade. 

 
 
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