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E-ISSN : 2541-5794  
   P-ISSN :2503-216X 

Journal of Geoscience,  
Engineering, Environment, and Technology 
Vol 5 No 3 2020 

 

 
Putra, A.Y., et al./ JGEET Vol 5 No 3/2020 151 

 

RESEARCH ARTICLE 
 

Groundwater Quality Assessment for Drinking Purpose Based on 

Physicochemical Analysis in Teluk Nilap Area, Rokan Hilir, Riau, 

Indonesia. 

Arief Yandra Putra1,*, Fitri Mairizki2  
1 Department of Chemistry Education, Faculty of Teacher Training and Education, Universitas Islam Riau, Pekanbaru, Indonesia 

2 Department of Geological Engineering, Faculty of Engineering, Univeristas Islam Riau, Pekanbaru, Indonesia. 
 

* Corresponding author : ariefyandra0811@edu.uir.ac.id 
Tel.:+62-813-7456-7116 
Received: August 1, 2020; Accepted: August 27, 2020.  

DOI: 10.25299/jgeet.2020.5.3.5488 

 
Abstract 

Groundwater is water resource that widely used for domestic purposes, including for drinking. However, the industrial and 

population growth causes the quality and quantity of groundwater to decline. In this case, the quality of drinking water in Indonesia must 

meet the requirements according to Health Minister Regulation No.492/MENKES/PER/IV/2010. This study aims are to determine the 

quality of groundwater in the research area based on physicochemical parameters and its evaluation for drinking water. Groundwater 

samples were taken from dug wells in Teluk Nilap area, Rokan Hilir, Riau. Groundwater samples have temperature average 30oC, TDS 

average 312,5 mg/L and pH average 5,6. Groundwater contain sulfate and nitrate with average value 48,8 mg/L and 11,86 mg/L, 

respectively. Groundwater water also have iron and lead metal above the permitted standard with average value 2,57 mg/L and 0,022 

mg/L. Groundwater in the study is not recommended as drinking water. 

Keywords: Groundwater, physical, chemical, drinking water 

 
 

1. Introduction 

Groundwater is one of the basic necessities for 
humans. Groundwater is a natural resource that needs to be 
preserved and   it   has   various   functions   to   support   
human   life. Groundwater is the main water resource that 
used for drinking water by community. Groundwater has 
many advantages compared to the other water resource 
such as : groundwater quality  is  better  than  surface  water  
quality,  groundwater quality does not depend on the 
season, there is a large amount of groundwater reserves and 
easy to obtain. However, population and industrial growth 
have caused the quality and quantity of groundwater to 
decline. One of the contributing factor is the presence of 
pollutants from garbage disposal area (Satrio, et al., 2017), 
industrial activities (Naslilmuna, et al., 2018)  and  
domestic  waste,  both  liquid  and  solid  waste (Sasongko, 
2014). 

The use of groundwater for domestic purposes 
including for  drinking  must  meet  the  requirements  
determined  by national and international regulations. In 
this case, the quality of drinking water in Indonesia must 
meet the requirements for physical, chemical, and biological 
parameters according to the Health Minister Regulation No. 
492/MENKES/PER/IV/2010. Drinking water must be free 
from harmful bacteria and chemical impurities. Drinking 
water also must be clean and clear,  odorless  and  colorless,  
have  no  suspended  matter or turbidity (Risky, D.P., et al., 
2017). It is necessary to monitor the quality of groundwater 
intensively and continuously to ensure that the 

groundwater used is suitable and safe for consumption. For 
this reason, a lot of research has been carried out on 
monitoring groundwater quality which used as a source of 
drinking water in various countries (Siringoringo, et al., 
2019) ; (Ibrahim, M.N., 2019) ; (Khan, A., Khan, M.A., 2018) 
; (Lalitha, B.V., 2016) ; (Annapoorna,  H.,  Janardhana,  M.R.,  
2015).  Therefore,  the aims of this research are to determine 
groundwater quality in study area based on 
physicochemical parameters and groundwater assessments 
for drinking purpose. 

2. Study Area 

Teluk   Nilap   is   one   the   villages   located   in   Kubu 
Babussalam Subdistrict, Rokan Hilir, Riau. Topographically, 
Teluk Nilap is low land with altitude about 6-10 m from sea 
level.  The  people  of  Teluk  Nilap  use  groundwater  for 
domestic purpose. However, at this time, the people in the 
study area feel a change in environmental condition 
including the decrease of groundwater quality. The 
groundwater looks brownish, oily, sticky to the skin and 
does not foam when given soap. Based on the regional map, 
stratigraphy of research area composed by young 
superficial deposits (Qh) and older superficial   deposits   
(Qp)   (Fig.1).   The   rocks   in   young superficial   deposits   
are   clays,   silts   and   clean   gravels, vegetation rafts and 
peat swamps. On the other hand, the older superficial 
deposits consist of clays, silts and clayey gravels, vegetation 
rafts. 

http://journal.uir.ac.id/index.php/JGEET
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152 Putra, A.Y., et al./ JGEET Vol 5 No 3/2020  
 

Fig. 1.  Regional  geological map of study area 

3. Methodology 

The groundwater samples were taken from dug wells in 
Teluk Nilap area with random sampling method. All 
samples were examined for physicochemical analysis in the 
Industrial Research and Standardization Laboratory, 
Padang.   The temperature, TDS and pH of collected 
samples were determined by using thermometer, TDS 
meter and pH meter, respectively.  Sulfate  and  nitrate  
concentrations  were determined by using 
Spectrophotometer. Iron and lead concentrations were 
determined by using Atomic Absorption 
Spectrophotometer. The quantitative data on 
physicochemical parameters obtained then compared with 
the drinking water quality standards based on Health 
Minister Regulation No.492/MENKES/PER/ IV/2010. 

4. Result and Discussion 

4.1 Temperature 

In   general,   temperature  condition  of groundwater  
is normal value, in range 27-31oC and average 30oC which 
meet the drinking water quality standard. The temperature 
standard permitted by Health Minister Regulation is air 
temperature ±3oC.  The  research  area  is  belongs  to  the  
tropical  climate. Water temperature can be affected by 
season, latitude, altitude, cloud cover, flow and depth of 
water. The large amounts of dissolved  chemicals  (phenol,  
sulfur)  and  decomposition  of organic matter by 
microorganism can also cause groundwater temperature 
value will be above standard limit  (Mairizki, F., 
Cahyaningsih, C., 2016). 

4.2 Total Dissolved Solid (TDS) 

TDS values of groundwater also show the normal value 
with  average  312,5  mg/L  in  range  101-809  mg/L.  TDS 
standard  permitted  by  Health  Minister  Regulation  is  
500 mg/L. Only 3 groundwater (20%) that have TDS value 
over the drinking water quality standard (Fig.2). All 
groundwater were  classified  as  fresh  water  (TDS  0-2000  
mg/L)  (Putra, D.B.E., et al., 2019). 

 
Fig 2. Total dissolved solid value of groundwater 

TDS consist of soluble organic or soluble inorganic 
compounds, minerals and dissolved gases. Salts that 
dissolve in groundwater which contain magnesium, 
sodium, sulfate or chloride ions also increase the amount of 
dissolved solids in groundwater. The presence of TDS such 
as sodium sulfate and magnesium sulfate can cause a 
change in groundwater taste. In addition, the high 
concentration of total dissolved solids affect the clarity, 
groundwater color and hardness (Firdaus, et al.,2017).  

4.3 pH 

pH condition of groundwater in range 2,8-6,6 and 
average 5,6. pH standard permitted by Health Minister 
Regulation  is 6,5-8,5. Almost all groundwater are acidic 
and do not meet drinking  water  quality standard  (Fig.3).  
This  is  due  to geological factors such as soil conditions. 
The study area is dominated by peat. 

pH value will determine the corrosion properties. The 
properties of corrosion will be higher at low pH. Water with 
low  pH  also  will  easily  dissolve  the  Fe  metal    that  form 
ferrous  and  ferric ions  which can  cause  the water  
become colored, smelly and have a taste (Putra, A.Y., 
Mairizki, F., 2019). 



 
Putra, A.Y., et al./ JGEET Vol 5 No 3/2020 153 

 

 

Fig 3. pH value of groundwater 

4.4 Sulfate 

Sulfate condition of groundwater show the normal value 
with average 48,8 mg/L in range 11,76-118,73 mg/L. 
Sulfate standard  permitted  by  Health  Minister  Regulation  
is  250 mg/L. All groundwater meet the drinking water 
quality standard (Fig.4). 

 
Fig 4. Sulfate value of groundwater 

The presence of sulfate in groundwater can be 
influenced by the type of rock that the groundwater passes 
through. Sulfates  are  found  in  sedimentary  and  igneous  
rocks  as sulfides   metal.   Sulfate   is   found   in   igneous   
rocks   as feldspatoid, and also found in many evaporite 
sedimentary rocks as gypsum, anhydrite and barite. In 
weathering, sulfur is oxidized to produce sulfate ions which 
are carried by groundwater (Mutianto, H., 2010). 

4.5 Nitrate 

Nitrate condition of groundwater also show the normal 
value in range 1,828-20,852 mg/L and average 11,86 
mg/L. Nitrate standard permitted by Health Minister 
Regulation is 50 mg/L. All groundwater have nitrate value 
below the drinking water quality standard (Fig.5). 

The presence of nitrate in high amounts at 
groundwater indicated the decomposition of organic 
compounds through biological processes with very low 
dissolved oxygen. Nitrate content in groundwater can also 
come from agricultural materials such as nitrate fertilizers. 
Nitrate residue will be carried  by  rainwater  into  the  soil  
which  increasing  nitrate values in groundwater 
(Sudaryanto, Suherman, D., 2008). 

 

 
Fig 5. Nitrate value of groundwater 

4.6 Iron 

Most groundwater have high concentration of Fe 
metal with average 2,57 in range 0,18-6,87 mg/L. Fe 
standard permitted by Health Minister Regulation is 0,3 
mg/L. Only 1 groundwater (6,67%) has Fe value below the 
drinking water quality standard while the others have 
high Fe metal content above the quality standard (Fig.6). 

 
Fig 6. Fe value of groundwater 

Heavy metals are naturally present in trace amounts in 
groundwater. The concentration of heavy metals in 
groundwater depends on the soil properties, the type of 
rock that the groundwater passes through and the influence 
of environmental pollution around the groundwater 
source. High concentration of iron metal will cause 
groundwater color will be yellowish, corrosion of metal 
objects, deposition of water pipe walls and accelerate the 
growth of Fe bacteria in groundwater (Rahadi, B., Lusiana, 
N., 2012). 

4.7 Lead 

Lead content in groundwater in range 0,0026 mg/L-
0,1316 mg/L and average 0,022 mg/L. Lead standard 
permitted by Health  Minister  Regulation  is  0,01  mg/L.  
6  groundwater (40%)  have  Pb  value  above  the  drinking  
water  quality standard while the others still have Pb metal 
content below the quality standard (Fig.7). This must be a 
concern because Pb can accumulate and pollute 
groundwater. 

The heavy metal content cannot be removed and it is 
toxic and carcinogenic. In humans, heavy metal can disrupt 
health depend on the part which are exposed of heavy 
metals. Heavy metal can cause cancer, allergies and at high 
dose can cause death (Yandra, A.P., Mairizki. F., 2020). 

 



 
154 Putra, A.Y., et al./ JGEET Vol 5 No 3/2020  
 

 
Fig 7. Pb Value of Groundwater 

5. Conclussion 

Groundwater samples were taken from dug wells in 
Teluk Nilap area, Rokan Hilir, Riau. All groundwater meet 
the requirements  for  drinking  water  quality  according  to  
the Health  Minister  Regulation  
No.492/MENKES/PER/IV/2010 in  terms  of  physical  
parameters  with  temperature  average 30oC and TDS 
average 312,5 mg/L. However, almost all groundwater   
does   not   meet   the   drinking   water   quality requirements 
based on its chemical parameters. All groundwater are 
acidic with pH average 5,6, containing sulfate and nitrate 
with average value 48,8 mg/L and 11,86 mg/L, respectively. 
Groundwater water also have iron and lead metal above the 
permitted standard with average value 2,57 mg/L and 
0,022 mg/L. Therefore, groundwater in research is not 
recommended as drinking water. 

Acknowledgements 

The authors would like to give an acknowledgment to 
Universitas Islam Riau and the Ministry of Education and 
Culture for providing research fund. Additional thank you 
for all students that help authors to collect data at field. 

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