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Journal of Geoscience,  

Engineering, Environment, and Technology 
Vol 6 No 3 2021 

 

 
Hadian et al./ JGEET Vol 6 No 3/2021  127 

 

RESEARCH ARTICLE 
 

Groundwater Conservation Strategy Based on Water Balance at 

Muarabungo Groundwater Basin, Indonesia 

Mochamad Nursiyam Barkah1, Fauziyah Hani2 , Bombom Rachmat Suganda1, 

Munib Ikhwatun Iman3, Cecep Yandri Sunarie
1, Mohamad Sapari Dwi Hadian1* 

1Water Center Geology Faculty,  Padjadjaran University, Jatinangor 45363, Indonesia. 
2Magister Program, Fakulty of Geology, Padjadjaran University, Jatinangor 45363, Indonesia. 

3Center for Groundwater and Environmental Geology, Geological Agency MEMR, Bandung, Indonesia.  

 

* Corresponding author : sapari@unpad.ac.id 

Tel.: +62-81321102268; fax: +62-22-7796545 [Tel./fax] 

Received: Oct 16, 2019; Accepted: Jun 20, 2021. 

DOI: 10.25299/jgeet.2021.6.3.3976 

 
Abstract 

Muarabungo Groundwater Basin,is locateed in Jambi and West Sumatra Province. Based on the four rainfall stations in Muaratebo, Dusun 

Rantau Pandan, Sungai Bengkal and Komplek Pengairan PU Station recorded in 2008 to 2011, the precipitation (ppt) in study area is 1799.09 

mm/year. Value of evapotranspiration (Evpt) in the study area is equal to 1261.26 mm / year (70.1%). Groundwater Basin of Muarabungo has an 
infiltration debit of 2,516,791,750 m3 / year and run-off debit (Ro) of 798 042 638 m3 / year. Rock composer in the Muarabungo Groundwater 

Basin are dominated by Alluvium Deposition, Quaternary rocks, and also the surrounding areas are composed by igneous and metamorphic rocks. 

Aquifer with a good productvity can be found on Alluvium and sedimentary rocks such as tuff sandy, whereas region without exploitable 
groundwater are composed by igneous rocks and metamorphic rocks. Based on groundwater quality, Groundwater Basin is divided into 13 facies, 

namely Ca; Cl, Mg; Cl, Na + K, Cl, Ca; HCO3, Mg; HCO3, Na + K; HCO3, Ca; No. dominant type, Mg; Nodominan type, Na + K; No. dominant 

type, No. dominant type; Cl, No. dominant type; HCO3, Nodominan type; SO4, and No. dominant type; No. dominant type. The result of water 

balance measurement in research area is used to show the areas for crisis and secure area. The water balance calculation and determining recharge 

and discharge areas are needed for developing conservation strategy. 

 
Keywords: Groundwater Basin, water balamce, aquifer, conservation, Muarabungo 
 

 

 

1. Introduction  

The population in Indonesia increased each year, including 

the Jambi Province. This in turn drive the high demand for clean 

water sourced from ground water. For ground water utilization, 

it must be known in advance the potential of ground water in 

the Muarabungo basin, both based on quantity and quality. Due 

to the groundwater use, groundwater basin potential must be 

balance with conservation efforts in order that optimal 

utilization and prevent environmental disaster such as 

groundwater depletion, flood in rainy season, and drought in 

dry season. Therefore, the potential of groundwater in each 

region is very important to know both the quantity and quality 

in determining an effective groundwater conservation strategy 

so that the sustainability of groundwater utilization will be 

guaranteed in the future. 

2. Research Method 

The research method uses primary data supported by 

secondary data. The data comes from government agencies 

such as Water Resources  Research Center and Development 

(PUSAIR), Statistic Center Agency (BPS), literature studies, 

and the Geological Agency. These data include, geological 

maps, hydrogeological maps, topographic maps, land use maps, 

rainfall data, climatology data, water use data, and population 

data. In addition there are data on the physical and chemical 

properties of groundwater in the study area. From the available 

data, the water balance is calculated using the Ffolliott method 

and groundwater quality is also determined from an analysis of 

the physical and chemical properties of the groundwater 

(Folliott, Baker, Tecle, & Neary, 2003). From the quantity and 

quality, the conservation strategy is determined at an altitude of 

42 - 133 meters.  

In general, groundwater is relatively acidic, possibly due to 

various factors. It could be due to water contact with the rocks 

that pass through it namely rocks from the Kasai Formation 

which consists of tidal rock rocks are acidic, tuff sandstones, 

with bentonite inserts and little lignite or due to acid rain due to 

air waste from coal mining. 

The following results of the analysis of the physical 

properties of groundwater in Muarabungo Groundwater Basin:  

Table 1. Analisys of Physical Properties Results of Water in 

Muarobungo Groundwater Basin  Area 

Physical Properties  Measurement 
Result 

Notes  

Water Temperature  26.2oC – 31.7oC - 

pH 4.2 - 8.8 Poor – Good Quality 

(Dephut, 2009) 
Electrical 

Conductivity  

0 – 340 µS/cm Fresh Groundwater 

(Mandel, 1981) 

Dissolved Solids 
Total  

0 – 150 mg/l Fresh Groundwater 
(Freeze & Cherry, 

1979) 

 

Groundwater chemical analysis was carried out at 54 points 

of interest. Groundwater quality was determined based on PP 

RI No. 20 of 1990 concerning Water Quality Criteria and SK. 

Men KLH No: Kep-02 / MENKLH / I / 1988 concerning Water 

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128  Hadian et al./ JGEET Vol 6 No 3/2021  
 

Quality Standards for Water Resources and Groups A and B 

and based on the Republic of Indonesia Ministerial Regulation 

Number 492 / MENKES / PER / IV / 2010 Concerning 

Drinking Water Quality Requirements. Here are the results of 

measurements of water samples: (M. S. D. Hadian & Rahmat, 

2015) 
Table 2. Comparison of Water Quality Based on Standards of Quality Standards and Field Conditions 

Element Measurement Result Max. Water Quality Standard Notes 

Ca 0 – 26.7 mg/l 200 mg/l Good Quality 

Mg 0.03 – 10.835 mg/l 150 mg/l Good Quality 

Na 0.33 - 14.55 mg/l 200 mg/l Good Quality 

Cl 0.97  - 18.5 mg/l 250 mg/l Good Quality 

SO4 0 - 14.46 mg/l 100 mg/l Good Quality 

HCO3 2.49 – 112.7 mg/l - - 

K 0.1 – 9.86 mg/l - - 

3. Groundwater Facies 

       Based on groundwater chemical data, groundwater facies 

were determined the study area development. The data is 

plotted to the Piper diagram (Figure 1). Plotting data into piper 

diagrams is assisted with rockworks15 software. From the 

results of the analysis of groundwater facies in the study area 

can be divided into 13 groundwater facies, namely the facies of 

Ca; Cl, Mg; Cl, Na + K; Cl, Ca; HCO3, Mg; HCO3, Na + K; 

HCO3, Ca; No dominant type, Mg; No dominant type, Na + K; 

No dominant type, No dominant type; Cl, No dominant type; 

HCO3, No dominant type; SO4, and No dominant type; No 

dominant type. (M. S. D. Hadian, Prayogi, & Azy, 2012) 

 

Fig 1.Results of groundwater chemical data plots into the Piper diagram 

4. Discussion 

Groundwater conservation is an effort to protect and 

maintain the condition and environment of the groundwater in 

order to maintain the sustainability or continuity of the 

availability in adequate quantity and quality, for the sake of the 

continuity of its functions and benefits to meet the needs of 

living things , both now and in future generations (Danaryanto 

& Darmawan, 2004, Kodoatie, Robert J. & Syarief, 2010). 

Groundwater conservation efforts that can be done at the 

Muarabungo Groundwater Basin include: 

4.1 Groundwater Preservation 

Groundwater preservation means groundwater extraction is 

limited to a safe amount, where the water uptake must be 

adjusted to the potential of available water and also does not 

cause negative impacts on the environment, such as the impact 

of groundwater level degradation 791,750 m3 / year. 

However, not all the potential water available can be 

extracted and used for daily needs. Therefore infiltrated water 

below the surface not only fill the aquifer, but also fill the 

unsaturated zone (unsaturated water) and the saturated zone 

(saturated water).  

 

Fig 2. Population Growth  in Muarabungo Groundwater Basin 



 
Hadian et al./ JGEET Vol 6 No 3/2021 129 

 

Specific yield is the ratio in percent (%) of the volume of 

water that can be taken from a soil or rock that is saturated with 

water compared to the total volume of rock or soil. This specific 

yield is a large amount of water available for human use. 

According to Todd (1980), Sy alluvium which consists of clay-

rich material is 3 - 28%, Sy sandstones 21-27%, and Sy tuff 

21%. The Muarabungo Groundwater Basin is dominated by 

alluvium and sandy tuff / sandstone tuff, so that each region is 

not permitted to use water exceeding 28% of the total water 

potential that is equal to 704,701,690 m3 / year. 

 

Fig 3. Estimated Groundwater Use Lines 

Based on the Figure 3, the amount of water usage (domestic 

water demand), predicted to reach a critical figure around 2030, 

assumed based on the average population growth results in 

2008-2013 (Source: BPS) which is 5.5%. The critical limit for 

water use is 28% of the potential water available. The amount 

of water used is only based on domestic water needs. This 

projection is only based on population growth, not yet projected 

by the influence of land use change. If the amount of 

groundwater use coupled with industrial and commercial needs 

and the effect of increasing runoff water coefficients are 

included, it is possible that critical water estimates will occur 

before 2033. Therefore, to avoid this happening, conservation 

must continue. 

4.2 Determination of groundwater catchment areas 

The determination of groundwater catchment areas is 

intended to be designated as a protected area by the local 

government. In accordance with Law Number 24 of 1992 

concerning Spatial Planning and Presidential Decree Number 

32 of 1990 concerning the Protection of Protected Areas is 

explicitly stated that water catchment areas are designated as 

protected areas where any cultivation activities are prohibited 

in those areas unless they do not disturb the protection function 

(M. Hadian, Mardiana, Abdurahman, & Iman, 2006). The 

function of water catchment areas is to supplement groundwater 

reserves. In this study, the water catchment area was determined 

based on buckling slopes (boundary morphology of the land 

with hills), the position of the emergence of springs, depth of 

ground water level, Ec and TDS values. 

 

Fig 4. Recharge and Discharge Zone Map 

4.3 Addition of groundwater recharge (artificial recharge) 

If groundwater utilization is increased, the groundwater 

refilling capacity can be artificially enlarged. Addition of 

groundwater recharge can be done by making rainwater 

collection ponds or catchment wells. The addition of 

groundwater recharge such as recharge wells generally can be 

applied to areas with high groundwater uptake with high 

population density areas from the surrounding area namely Kec. 

Pasar Muarabungo with a density of 2,631.13 inhabitants / km2 

(BPS Bungo District, 2013). Wells infiltration aim to increase 

water infiltration in open areas such as fields, parking lots, 

yards and so on. Furthermore the construction and depth 

adapted to local soil conditions. 

Rainwater collection ponds are ponds or containers used to 

collect rainwater. This method can be applied in the area around 

the Muaratebo Station and Bengkal River because it is noted 

that the rainfall in this area is smaller than other stations it can 

be seen in Figure 2. The main objective is to raise the 

groundwater level, and also to store excess water reserves when 

it rains , so that there are water reserves during the dry season. 

This method has a direct effect on free groundwater in the 

shallow aquifer layer, and is effective for replenishing water 

into the deep aquifer layer. 

4.4 Public Outreach 

Some people's misunderstanding about all matters relating 

to groundwater sometimes makes groundwater users not pay 



 
130  Hadian et al./ JGEET Vol 6 No 3/2021  
 

attention to the conservation of groundwater, such as disposal 

of household waste and disposal of sewage (feces) that do not 

meet the requirements and that can pollute groundwater. 

Therefore the understanding of groundwater resources and the 

proper use of groundwater needs to be socialized to the 

community in this groundwater conservation effort. 

5. Conclusion 

Based on water balance calculations, all areas in the 

Muarabungo Groundwater Basin are still in a safe zone, there 

are no crisis areas. This area has underground water potential of 

2,516,791,750 m3 / year and surface water of 798,042,638 m3 

/ year. The assumption of water use in the Muarabungo 

Groundwater Basin is 29,565,821.25 m3 / year. Based on the 

physical and chemical properties of groundwater, groundwater 

quality in the Muarabungo Groundwater Basin is quite good. 

It's just that the pH value in some places is quite acidic. 

Conservation strategies that can be carried out include: 

• Groundwater preservation 

Intake of water must be adjusted to the potential of available 

water. Potential water availability is 768,476,816.75 m3 / year 

• Determination of Groundwater Absorption Areas 

Based on the analysis results, the recharge area is estimated to 

be in Kec. Punjung Island, Tabah,.  

Padang Laweh, Jujuhan, Tanah Tumbuh, Tanah Sepenggal, 

Maro Sebo Ulu, and Muara Tabir. 

• Addition of groundwater additives (artificial recharge) 

Addition of groundwater recharge can be done in areas with 

high population density. The highest population density in the 

study area is in Pasar Muarabungo District, which is 2,631.13 

people / km2 (BPS Bungo District, 2013). 

• Community Outreach 

This is done so that the community understands about all 

matters relating to groundwater so that in the implementation of 

groundwater utilization so that the community can pay attention 

to the conservation of groundwater. 

Acknowledgement 

The authors thank the Unpad Postgraduate School Dean 

Prof. Dr. Hendarmawan, M.Sc, Head of the Environmental 

Geology Laboratory, Faculty of Geological Engineering, 

Padjadjaran University, Rudi Suhendar Head of the Geology 

Agency who has facilitated all needs and provided the data 

needed for the purposes of this research. 

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