Microsoft Word - 14-Bio_41819


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Bioscience Journal  Original Article 

Biosci. J., Uberlândia, v. 35, n. 2, p. , Mar./Apr. 2019 
http://dx.doi.org/10.14393/BJ-v35n2a2019-41819 

VARIATION OF THE WATER TABLE AND SALINITY IN ALLUVIAL 
AQUIFERS OF UNDERGROUND DAMS IN THE SEMI-ARID REGION OF 

RIO GRANDE DO NORTE, BRAZIL 
 

VARIAÇÃO DO NÍVEL FREÁTICO E DA SALINIDADE DO AQUÍFERO ALUVIAL 
EM BARRAGENS SUBTERRÂNEAS NO SEMIÁRIDO DO RIO GRANDE DO NORTE 

 
Alexandre de Oiveira LIMA1; Francisco Pinheiro LIMA-FILHO2; Nildo da Silva DIAS3;  
René Chipana-RIVERA4; Miguel FERREIRA NETO3; Anderson de Medeiros SOUZA5; 

Priscila Regina do Aragão REGO6; Cleyton dos Santos FERNANDES7* 
1. Professor, Universidade do Estado do Rio Grande do Norte, Mossoró, RN, Brazil; 2. Professor, Universidade Federal do Rio Grande 
do Norte, Natal, RN, Brazil; 3. Professor, Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brazil; 4. Professor, Universidad 

Mayor de San Andrés, La Paz, Bolívia; 5. Professor, Instituto Federal da Paraíba, Picuí, PB, Brazil; 6. Instituto Nacional de Colonização 
e Reforma Agrária, Natal, RN, Brazil; 7. Doutorando em Fitotecnia, Universidade Federal Rural do Semi-Árido, Mossoró, RN, Brazil, 

cleyton1959@hotmail.com. 
 

ABSTRACT: Despite the growing progress in the construction of underground dams, there are few 
studies to evaluate and monitor these reservoirs after their construction. Thus, a research study was carried out 
to evaluate the water table level in alluvial aquifers and water salinity in four underground dams selected in the 
Cobras river basin, Parelhas municipality, Rio Grande do Norte. Water level variation was monitored using the 
traditional method and the Ground Penetrating Radar with generation of 3D virtual models. Water samples 
were collected between the months of December 2010 and December 2011 for electrical conductivity analysis. 
The results indicate that the accumulation of groundwater and salinity (expressed by electrical conductivity) in 
the reservoirs were affected by the spatial position within the hydrographic basin (limited occurrence of alluvial 
aquifer recharge area in headwater sectors) and the presence of surface reservoirs (upstream dams), which 
promote a more continuous recharge, greater renovation, and reduction of the salinity of the waters of the 
alluvial aquifer downstream. 

 
KEYWORDS: Salinity. Desertification. Hydrochemistry. 

 
INTRODUCTION 
 

The growing demand for water for human 
supply is making countries maximize the use of 
their water reserves. In this context, alternatives 
have been used to increase water availability, 
mainly for the diffuse rural demand existing in arid 
and semi-arid zone (LIMA et al., 2013). 

In recent years, the number of underground 
dams built in Brazil has increased, especially due to 
the increased Federal public financing, which has 
prioritized this technology to meet the water needs 
of rural populations. 

In spite of the quantitative advances, there is 
little research on the environmental impacts of this 
technology after their construction, involving 
aspects such as temporal variation and evolution of 
salinity, and variation of the water level in artificial 
underground deposits. These parameters are 
important to guarantee the sustainable use of water 
by the communities and families that benefit from 
this rainwater collection and storage technology 
(SHADEED; LANGE, 2010). Therefore, greater 
attention must be paid to the management and 

monitoring of groundwater in a sustainable manner, 
that is, without causing environmental, economic or 
social consequences (RAJU et al., 2006; ERTSEN; 
HUT, 2008; EL-HAMES, 2011; SANTOS et al., 
2016). 

A study carried out by Fontes Junior et al. 
(2012) brings important contributions to understand 
the water quality dynamics from underground dams. 
However, these investigations do not include a study 
integrating geological sciences (in particular 
hydrogeology), with the spatial position within the 
hydrographic basin associated with existing surface 
and underground deposits, and local rainfall. 

In this context, the objective of this work 
was to evaluate water salinity and groundwater level 
variation in the alluvial aquifer in four underground 
dams of the micro basin of the Cobras river, RN, in 
the Brazilian semi-arid zone. 

 
MATERIAL AND METHODS 
 
Characterization of the study area 

The studies were carried out in four 
underground dams of the micro basin of the Cobras 

Received: 19/04/18 
Accepted: 10/10/18 



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river, in the semi-arid region of the state of Rio 
Grande do Norte. An outstanding characteristic of 
this micro basin is its location within the area 
considered as one of the most affected by the 
desertification process, being inserted in the Seridó 
desertification nucleus (NUDES). The climate of the 
region is classified as BSw`h according to criteria 
established by Köppen (BRASIL, 2002). Based on 
information from the meteorological station of the 
municipality of Parelhas/RN, it was possible to define 
that the rainy season occurs between January and 

May, with an average annual rainfall of 612.4 mm, 
average annual temperature of 26.1 °C, with a 
minimum of 21.1 °C and a maximum of 32.0 °C. 

 
Monitoring of water level 

The investigation was carried out in three 
underground dams (UD1, UD2 and UD4). These three 
were chosen because they were built at the same 
time, year 2010, and because they were located in the 
upper, middle and lower part of the watercourse of 
the micro basin (Figure 1). 

 

 
Figure 1. Location of the underground dams (UD) monitored along the micro basin of the Cobras river, RN, 

2010. 
 

Measuring water levels of wells in the 
hydrographic basin was also monitored monthly, 
using a manual level meter (traditional method). In 
the case of UD1, the Ground Penetrating Radar 
method was also used and generated 3D virtual 
models of the alluvial body, corresponding to the 
water accumulation area of the underground dam. 

 
Monitoring of groundwater electrical conductivity 

Samples for analysis of the water Electrical 
Conductivity (ECw) were collected monthly between 
the months of January and December 2011. The 
ECw was measured and monitored with a portable 
conductivity meter model Oakton PC 10 series, 
obtaining the temporal variation of water salinity. 

Groundwater electrical conductivity (ECw) 
was monitored in four underground dams, which 
are: UD1, UD2, UD4 (dams built in 2010) and UD3 
(dam built in 1983) (Figure 1). The first collection 
of samples was carried out in December 2010, at the 
end of the dry season of the year, while the second 
and third collections were made at the end of the 

rainy and dry season of the year 2011 (June and 
December months, respectively). 

The criteria for the selection of the 
underground dams were: a) positioning of the 
underground dam in relation to the areas with springs 
and to the course of the main river (high, medium and 
low); b) proximity to surface dams, to evaluate the 
influence of the integration of surface and 
groundwater; c) time of construction and operation 
and d) control in the exploitation of water. 

The collected water samples were kept in 500 
mL plastic containers and then taken to the Soil and 
Water Laboratory of the Agricultural Research 
Company of Rio Grande do Norte (EMPARN) for 
ECw analysis. 

 
GPR imaging and 3D virtual modeling 

For this procedure, only the underground 
dam UD1 was selected and the area within the 
hydrographic basin was imaged to detect basement 
irregularities, the sedimentary package and the height 
variation of the groundwater level in the studied 



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period. The choice of only one dam was based on an 
experiment and on the belief that the imaging of one 
dam represents the others. 

The GPR used was the Sir 3000 model of 
Geological Survey Inc (GSSI) with shielded 
antennas, resistant connectors, coated and sealed 
electronic boards, shielding to eliminate interference 
generated on the ground. After field data 
acquisition, these were processed in Reflex 5.0 
software. In the next step, the radar images were 
exported and interpreted in the software Opendtect v 
4.4.0, where the 3D model of the alluvial body 
imaged was created. 

 
Data analysis 

The salinity of the groundwater (expressed 
by the electrical conductivity) of the micro basin 
was compared with the rainfall and the variation of 

the water level monitored during the collection 
period, and these were plotted using Excel 2010 
software. 

 
RESULTS AND DISCUSSION 
 
Characterization of water salinity in 
underground dams 

In the collection of samples made at the end 
of the dry season, in the month of December 2010 
(corresponding to the first water collection), the ECw 
increased from upstream to downstream, while in 
the second collection carried out in June 2011, end 
of the period in which the dams were at maximum 
storage capacity and dilution, as well as in the third 
collection (end of the dry period, December 2011), 
the increase in water salinity in the downstream 
direction ceased to exist (Figure 2). 

 

 
Figure 2. ECw of the water in underground dams located along the micro basin of the Cobras river, 

Parelhas/RN, in the period 2010-2011. 
 

This aspect can be explained by the water 
accumulation with the functioning of underground 
dams, which naturally changed the flow dynamics in 
terms of the presence, accumulation and dilution of 
the salts. In this condition, salinity is strongly 
influenced by factors related to the capacity of 
accumulation and water recharge existing in each 
underground dam or alluvial aquifer, which in turn 
reduces ionic concentration (ANDRADE et al., 
2010, BAHIA et al., 2011 ; LIMA et al., 2013). 

The water samples collected in the months 
of July and December of 2011 (rainy and dry 
periods, respectively) in the dams located 
downstream of the basin (UD3 and UD4), due to the 
large recharge area showed higher effects of ions 
dilution and the consequent reduction of ECw in 
comparison to samples collected in December 2010 

(dry). Another aspect worth mentioning is that, 
although UD3 has been built twenty-seven years ago 
and UD4 was only one year old, these dams had very 
close ECw values. One of the possible explanations 
for the control of salinity in UD3 over the years is 
the frequency of water use for domestic 
consumption of five families, about 270 m3 of water 
per month. 

Although studies must continue in other 
underground dams, these results indicate that if 
there is consumption there will be renewal of water 
and salts, therefore the salinization process will not 
be triggered. Other studies also show that rainfall 
and the continuous use of water from an 
underground dam exert a strong influence on 
salinity levels in dry periods of the year (LOPES, 
2013, LIMA et al., 2017). 



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Variation of salinity associated with the water 
level of underground dams 

The water stored in the UD1 had a reduction 
in the ECw between the months of January and 
March 2011 due to the rainy season in the region 

(Figure 3). This reduction in ECw was possibly due 
to the dilution of the salts present in the deposit by 
the rainwater. As of the month of April, the gradual 
increase in ECw predominated, reaching 0.85 dS m

-1 
in December. 

 

 
Figure 3. Monthly variations of ECw and depths of the water table of UD1, upstream, near the source in the 

micro basin of the Cobras river, RN, between January and December 2011. 
 

With respect to the variation of the 
groundwater level of UD1, there is an elevation of 
the water table (decreasing its depth and tending to 
be flat) between January and March 2011, as can be 
seen in Figure 3. This fact is associated with the 
water supply coming from the recharges by the 
precipitations that occurred in the period. Between 
March and May there is a stabilization of this 
fluctuation, while a gradual decline of the water 
table begins in May, resulting in an almost total 
emptying of the underground dam, in the middle of 
December. 

With the descent of the phreatic level, water 
salinity increased in the alluvial aquifer (Figure 3), 
establishing a relation between the greater depth of 
the phreatic level, greater emptying of the reservoir, 
and greater concentration and/or precipitation of 
salts, especially salts with lower solubility. 

Usually alluvial aquifers, in the areas closest 
to the springs/headwaters, have limited 
accumulation/retention potential of the recharge 
waters, and are easily affected by dry periods or by 
large exploitations, due to the reduced size of the 
alluvial sedimentary deposits associated with greater 
slope and gradient in the headwaters of the river 
basin, which interfere in the sedimentary dynamics. 

In this case, the transport of sediments in the 
headwaters of rivers exceeds the deposition, and the 
lower the alluvial sediment deposition, the lower the 
capacity of the alluvial aquifer reservoir to be 
formed upstream of the underground dams, limiting 

the formation of saturated thicknesses and 
underground reserves. 

Lima et al. (2013) show the importance of 
not constructing underground dams near the springs 
due to the limited accumulation / retention capacity 
of the recharge waters. Cirilo et al. (2003), when 
evaluating underground dams constructed in the 
state of Pernambuco, also pointed to this limited 
recharge area as one of the main causes of the 
failure of some underground dams in that state. 

In relation to UD2 (Figure 4), the variations 
of ECw and water table level were very different 
from those observed in UD1, that is, there is no clear 
relation between ECw increase with groundwater 
retraction (increase in depth). The variation of the 
water table in UD2 was approximately 0.57 m, value 
much lower than the 2.85 m found in UD1 (Figure 3) 
and the 3.08 m observed in UD4 (Figure 5). As of 
July, there is a gradual decrease of both monitored 
parameters until the month of October, during which 
time the water table continues to fall and the salinity 
starts to have a slight tendency to increase. 

It was also verified, as already observed for 
the water table, a low amplitude of variation of ECw 
in UD2. This specific characteristic can be explained 
by the presence of a dam upstream of this 
underground dam. This water body maintains a 
continuous recharge of the alluvial aquifer in the 
downstream section over time, a fact that can lead to 
less abrupt changes in salinity at the moment of 
rainfall, as occurred in UD1. 
 



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Figure 4. Monthly variations of ECw and depths of the water table of UD2, in the micro basin of the Cobras 

river, RN, between January and December 2011. 
 

Thus, the influence of surface works, such 
as the dams built along the semi-arid basins, which 
influence the frequency of recharge, renewal and 
reduction of the salinity of the alluvial aquifers of 
the underground dams, suggesting the need for 
integrated management of surface and groundwater. 

Regarding UD4, it was observed that the 
rains tend to occur between January and April, 
reducing from May to December. The beginning of 
the occurrence of the rains also marks the period of 
recovery/rise of the water table (becoming flatter), 
in general between January and April, remaining at 

a constant level until the beginning of June, and then 
progressively decreasing to a critical level in the 
month of December, when the saturated thickness of 
the aquifer is very small or zero. 

In relation to the electrical conductivity of 
water in UD4 (Figure 5), with the increase of rainfall 
between January and April, there is a tendency of 
ECw reduction, which shows an abrupt fall between 
January and February (probably due to the dilution 
of salts with recharge of the aquifer), and a 
continuous and progressive trend of reduction from 
February to December. 

 

 
Figure 5. Monthly variations of ECw and depths of the water table of UD4, in the micro basin of the Cobras 

river, RN, between January and December 2011. 
 

Two aspects deserve to be highlighted in 
UD4; the first was the high ECw reduction, reaching 
December with the lowest water salinity (0.813 dS 
m-1) among the three dams monitored. The second 

was that between the beginning and the end of the 
monitoring (January and December 2011) the water 
table level increased by 0.87 m (Figure 5). It should 



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be noted that at the beginning of monitoring this 
underground dam had the highest salinity. 

A common feature in the three monitored 
dams was that since June there was a gradual 
reduction in the water table, although with different 
intensities, mainly in UD2, since the deposits did not 
remain static. 

Three factors may explain this phenomenon: 
the first refers to the decrease of rainfall as shown in 
Figures 3, 4 and 5; the second, and most probable, 
results from the existence of fractures, very common 
in the crystalline basement of the region in which 
the micro basin is inserted, located under the 
influence of metamorphic mica schists of the Seridó 
Formation. This type of rock has generally vertical 
foliations which would facilitate the losses in the 
reservoirs, making it possible for the water 
accumulated in the underground dams to feed the 
fissure aquifer and maintain the waters of this 
reservoir with salinity levels lower than those in 
other regions of the Rio Grande do Norte state. 
Thus, when planning the underground dams, this 
fracturing condition of the crystalline basement that 

serves as the basis for the reservoir needs to be 
observed with greater attention. For Cirilo et al. 
(2003), in a study of underground dams monitoring, 
stated that problems related to the placement of the 
impermeable septum (200-micron-thick plastic 
tarpaulin) are one of the main factors of failure of 
underground dams. The third factor is related to 
losses by the impermeable septum used to block the 
passage of water. 

 
Water level imaging in UD1 

The literature on water level imaging in 
underground dams in the northeastern semi-arid 
region is very scarce, making it difficult to discuss 
the results obtained in this study. 

The water table in the entire catchment area 
of the underground dam UD1 was identified in the 
3D GPR profile (Figure 6). Lahouar and Al-Qadi et 
al. (2014) reported good sensitivity of the GPR to 
map the water level and its temporal variation, since 
they were able to detect the presence of the water 
table within multiple and ambiguous reflectors to a 
depth of approximately 8 m. 

 

 
Figure 6. Imaging of the crystalline basement of the hydrographic basin area (A), topographic surface and 

crystalline basement (B), view of the reservoir, highlighting the water level in the imaging (C) and 
lateral view of the basin of the monitored underground dam (D). 

 
The water level generates a reflection with 

higher energy due to the decreasing velocity at the 
water level, as well as the difference in the dielectric 
properties of the fluid in comparison to the other 
materials in the place (CASSIDY, 2007). 

In the case of the use of GPR for the leasing 
process in an area where there is a high water table, 
depending on recharge process in that location, it 

will be possible to determine its position, and with 
that, to anticipate additional costs arising from the 
need for lowering the water level. In addition to this 
factor, additional care with the people involved with 
the construction process may have an impact on the 
financial costs of the work. In this way, the 
information generated with the previous imaging 



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will be of fundamental importance for the planning 
of the process of construction of underground dams. 

Therefore, it will be possible to propose a 
model of sustainable management of aquifers, 
allowing a planning that takes into account local 
water availability with the needs of rural 
communities, in order to ensure access to water 
during the most critical period of the year. 

 
CONCLUSIONS 
 

The accumulation of water and the salinity 
of the groundwater of the alluvial aquifer in the 
underground dams are strongly influenced by the 
spatial position within the hydrographic basin 
(limited occurrence of recharge area due to lower 
deposition rate and accumulation of alluvial 
sediments in headwater sectors of the river), 
presence of surface reservoirs (upstream dams), 
which promote a more continuous recharge, greater 
renovation, and reduction of the salinity of the 
waters of the alluvial aquifer downstream. 

The open fracture planes of the fractured 
crystalline aquifer rocks may favor a greater transfer 
of water from the overlying alluvial aquifer by 
descending vertical drainage to the underlying 
crystalline aquifer, which could promote the 
renewal of alluvial aquifer reserves and reduce the 
salinity of the groundwater. 

However, this structural conditioning and 
hydraulic interconnection between the alluvial 
aquifers and the underlying "fractured" aquifer need 
to be studied, confirmed and quantified in greater 
detail in the light of temporal and spatial monitoring 
data in the area, with no elements still to affirm that 
these factors act decisively to diminish the salinity 
of the waters of the alluvial aquifer implanted in the 
underground dams in the studied domain. 

The 3D GPR profile method of the alluvial 
body, corresponding to the UD1 hydrographic basin, 
identified the irregularities of the basement, the 
space occupied by the sedimentary package and the 
water table of the reservoir, and could be used later 
to monitor the water level fluctuation in these 
reservoirs. 

 
 

RESUMO: Apesar do crescente avanço na construção de barragens subterrâneas, há poucos estudos de 
avaliação e monitoramento das barragens subterrâneas após a sua construção. Assim, foi realizada uma 
pesquisa com o objetivo de avaliar a salinidade da água e a variação do nível freático em aquífero aluvial em 
quatro barragens subterrâneas selecionadas na microbacia do rio das Cobras, município de Parelhas, Rio 
Grande do Norte. As amostras de água foram coletadas entre os meses de dezembro de 2010 a dezembro de 
2011 para análise da condutividade elétrica. A variação do nível da água foi monitorada utilizando método 
tradicional e o Ground Penetrating Radar com geração de modelos virtuais 3D. Os resultados indicam que a 
acumulação da água subterrânea e a sua salinidade (expressa pela condutividade elétrica) nos reservatórios 
foram afetadas pela posição espacial dentro da bacia hidrográfica (ocorrência limitada de área de recarga do 
aquífero aluvial em setores de cabeceiras do rio) e pela presença de reservatórios superficiais (açudes à 
montante), os quais promovem uma recarga mais contínua, maior renovação, e redução da salinidade das águas 
do aquífero aluvial à jusante. 

 
PALAVRAS-CHAVE: Salinidade. Desertificação. Hidroquímica. 

 
 
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