INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,

MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)

ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue V, May 2024

www.ijltemas.in Page 209

Determination of Water Quality Index (WQI) of Selected Rivers in

Ezeagu Local Government Area of Enugu State, Nigeria

Okoye, N.H., Anarado, I.L

., Anarado, C.J.O., Muobike, C.M., Okonkwo, N.A., Ikeh ,O.A.,

Onukwube, N.D., Izuka, E.C.

Department of Pure and Industrial Chemistry, Nnamdi Azikiwe University, Anambra State

*Corresponding author

DOI : https://doi.org/10.51583/IJLTEMAS.2024.130521

Received: 18 May 2024; Accepted: 29 May 2024; Published: 22 June 2024

Abstract: Assessment of water quality of Ajali, Karawa and Nnam rivers in Enugu State, Nigeria, was determined over a 10

year-span, in order to ascertain the level of deterioration of the water over time. Water samples were collected in 2013 and 2023

from the aforementioned rivers. For these 2years, the samples were collected in April and July to represent early rainy season and

peak rainy season respectively. The physicochemical parameters such as pH, electrical conductivity, total hardness, total

suspended solids, total dissolved solids, alkalinity, dissolved oxygen, biochemical oxygen demand, calcium, magnesium,

sulphate, nitrate and chloride were determined using standard methods. The water quality indicator ranges were found to be as

follows: pH: 4.10–9.23, electrical conductivity (μs/cm): 6.88-53.30, total hardness (mg/L): 4.00-220.00, total suspended solids

(mg/L): 0.002-91.00, total dissolved solids (mg/L): 0.08-9.52, alkalinity (mg/L): 10.00-31.50, dissolved oxygen (mg/L): 0.25-

36.80, biochemical oxygen demand (mg/L): 0.05-73.60, calcium(mg/L): 0.31-9.40, magnesium (mg/L): 0.003-0.68, sulphate

(mg/L): 119.35-425.65, nitrate (mg/L): 0.07-36.80, chloride (mg/L): 3.60-30.00. The WQI values of the three rivers were as

follows: 72.93, 78.93 and 66.17 in April 2013; 47.34,85.79 and 75.81 in July 2013, while 425.3, 194.1 and 242.0 in April 2023;

70.68, 50.61 and 62.95 in July 2023 for Ajali, Karawa and Nnam rivers respectively. Ajali and Karawa river water were only

suitable for drinking in July 2013 and July 2023 respectively. All the April samples show high level of deterioration and as such

is very poor and unfit for human consumption. Generally, there was an increasing trend in the pollution level of the rivers over

the period. The need for appropriate treatment cannot be over-emphasized,

Keywords: Ajali, Karawa, Nnam, physicochemical properties, water quality index, rivers

I. Introduction

A river is a naturally occurring surface water with defined banks. It is essential for setting national development goals as well as

those of the entire world because it touches on every aspect of the ecosystem and human endeavour while promoting national and

human wealth, civilization and educational attainment. (UN-waters, 2016; Smith et al., 2019). In most cases, it provides drinkable

water in areas where groundwater resources are insufficient or non-existent (Seiyaboh et al., 2017). Surprisingly, the

indiscriminate discharge of sewage and industrial waste, along with a multitude of human activities that impact its

physicochemical and microbiological quality, are polluting this vital natural resource for human progress. (Chauhan and Singh,

2010). One of the most basic human rights—access to clean water has been undermined by the global decline in river water

quality. This problem continues to be a major focus of the UN water campaign, especially in the world’s poorer nations (Ibrahim

et al., 2015). The global degradation of freshwater quality is a threat to the world’s economy and health (Barbosa et al., 2016;

Nwabor et al., 2016; Otene and Nnadi, 2019; Zakir et al., 2020; Bhutiani et al., 2021), particularly in developing nations like

Nigeria where policies and laws are rarely implemented (Iloba, 2021). Therefore, it is crucial to make sure that this limited

resource is used appropriately, accepted, and upholds water quality requirements while maintaining its primary usage. Two

reliable indices that offer helpful information on water quality are the comprehensive pollution index and the water quality index

(WQI). The Water Quality Index (WQI) is a numerical value that lacks units and represents the overall quality of water by

categorizing it based on its suitability for residential use.

(Tyagi et al. 2013). The objective of water quality index is to turn complex water quality data into information that is

understandable and used by the public (Thakor et al, 2011). Many researchers have worked on water quality index of many rivers

in and outside the country, but with limited knowledge on the extent of degradation over time. This study aims to assess the water

quality of Ajali, Karawa and Nnam rivers in Enugu State, Nigeria, over a 10 year-span, in order to ascertain the level of

deterioration.

II. Matrerials and Method

Study Area

Ajali, Karawa and Nnam Rivers are located in Ezeagu Local Government Area of Enugu State. It shares boundary with Udi Local

Government Area, Oji Local Government Area and Uzo-Uwani Local Government Area.

INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,

MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)

ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue V, May 2024

www.ijltemas.in Page 210

Fig 1: Map showing the sampled rivers in study area.

Sample collection:

Clean and sterilized air-tight plastic bottles were used to collect the samples. Equal volumes of the samples were collected from

different points of the river to ensure good representation of the entire body of the water. For these 2 years (interval of 10 years),

the samples were collected in April and July to represent early and peak of rainy season.

Sample Analysis

Total hardness as well as calcium and magnesium were measured using ethylenediaminetetraacetic acid (EDTA) titrimetric

method (Smith 1999). pH was determined with pH meter (model 3510). Chloride (Cl

) was determined by Mohr’s Argentometric

method using silver nitrate (Eaton et al. 2005). total dissolved solids (TDS) and electrical conductivity (EC) were done using

Hanna multimeter with replaceable electrodes (Hanna HI 9811-5 multi-meter). Phosphate (PO

3−

) was measured colorimetric

ally using the ascorbic acid method (Murphy and Riley 1962; Edwards et al. 1965). Nitrate (NO

−

) concentration was determined

using cadmium reduction method (Eaton et al. 2005). All other parameters were analysed using standard methods (APHA 2012).

Water Quality Index method

The water quality index (WQI) was evaluated by using the weighted arithmetic water quality index method (Egun and Oboh

2021; Egun and Ogiesoba-Eguakun 2018; Oboh and Agbala 2017; Tyagi et al., 2013). The reference standard used for the

computation was the World Health Organisation standard for drinking water quality (WHO, 2017). The WQI was computed from

Eq. (1):



















(1)

Where, qn = Quality rating of n

water quality parameter. Wn= Unit weight of n

water quality parameter

Quality rating (qn)

The quality rating (qn) is calculated using the expression given in Equation (2).







󰇳

󰇛









󰇜

󰇛









󰇜

󰇴

  (2)

Where, Vn = Estimated value of n

water quality parameter at a given sample location.

Vid = Ideal value for n

parameter in pure water. (Vid = 0 for all parameters except pH (with a value of 7.0) and dissolved

oxygen (with a value of 14.6 mg/L) Sn = Standard permissible value of n

water quality parameter.

INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,

MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)

ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue V, May 2024

www.ijltemas.in Page 211

Unit weight

The unit weight (Wn) is calculated using the expression given in Equation (3).













(3)

Where, Sn = Standard permissible value of n

water quality parameter. k = Constant of proportionality and it is calculated by

using the expression given in Equation (4).



󰇩











󰇪

 (4).

WQI values are categorized into five classes based on the weighted arithmetic water quality index method (Tyagi et al. 2013) as

follows: 0–25 (excellent water quality), 26–50 (good water quality), 51–75 (poor water quality), 76–100 (very poor water

quality), and > 100 (water unsuitable for drinking).

III. Results and Discussions

A summary of the values of some physicochemical properties of the various rivers are presented in Tables 1, 2 & 3. The mean pH

values range from 4.90 - 9.12, 4.15 - 9.23 and 4.10 – 8.92 for Ajali, Karawa and Nnam respectively. Showing a slight deviation

from the stipulated limit by the World Health Organization (WHO, 2017). The higher pH values recorded in Ajali River can be

attributed to washing of clothes in the river and processing of tapioca and cassava (Okoye et al. 2009; Ogbu et al. 2016). Iloba,

et al., (2021), recorded a minimum pH value of 5.3. Otokune for and Obiukwu (2005) and Ekhaise and Anyasi (2005) reported an

alkaline pH range of 8.3 to 8.5 in river water in Niger Delta, South-eastern Nigeria and 8.8 to 9.1 in Ikpoba River, Nigeria,

respectively. The highest concentration of electrical conductivity (53.30 μS/cm) was obtained during the early rainfall from Ajali

River. Karawa river recorded lowest value for electrical conductivity (6.88 μS/cm) in April 2013 and highest (13.4 μS/cm) in

April 2023. This is lower than the values obtained by Alum and Okoye (2020) who reported electrical conductivity value in the

range of 88.00 to 225.00 μS/cm for the same Karawa river. Parameters like electrical conductivity, total hardness and nitrate

though within the permissible limit by WHO, show an increase in concentration in April and July 2023 when compared with

values obtained in April and July 2013. In general, the mean values range for parameters like electrical conductivity (μs/cm), total

hardness (mg/L), total suspended solids (mg/L), total dissolved solids (mg/L), alkalinity (mg/L), calcium(mg/L), magnesium

(mg/L), sulphate (mg/L), nitrate (mg/L) and chloride (mg/L) were within the permissible limit (WHO, 2017). Higher values for

TSS, TDS & Cl

have been reported for river water from Ajali (Nwerem et al., 2023). Also, Alum and Okoye (2020) reported

higher values for some parameters (EC, TDS, TH, magnesium, chloride, nitrate) for water sample from Ajali and Karawa river.

Table 1. Physicochemical parameters of Ajali river

Parameter

2013

2023

WHO

April

July

April

July

8.77

4.90

8.485

9.12

6.5-8.5

Electrical Conductivity (μs/cm)

21.60

24.20

53.3

31.9

250

Total Hardness (mg/L)

40.0

36.00

140

300

TSS (mg/L)

80.0

91.00

0.006

15.91

250

TDS (mg/L)

20.0

43.00

26.6

0.08

500

Alkalinity (mg/L)

31.5

10.00

120

DO (mg/L)

0.25

11.00

36.8

8.2

BOD (mg/L)

0.05

1.10

73.6

0.1

(mg/L)

5.40

1.54

0.385

0.56

(mg/L)

0.32

0.085

0.45

(mg/L)

164.4

329.20

164.55

119.35

500

(mg/L)

1.106

1.46

3.402

31.20

(mg/L)

3.60

21.00

4.998

4.99

250

ND = Not Detected

INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,

MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)

ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue V, May 2024

www.ijltemas.in Page 212

Table 2. Physicochemical parameters of Karawa river

Parameter

2013

2023

WHO

April

July

April

July

9.23

4.15

8.56

9.05

6.5-8.5

Electrical Conductivity (μs/cm)

6.88

11.81

13.4

12.08

250

Total Hardness (mg/L)

4.0

30.00

185

300

TSS (mg/L)

0.9

4.50

0.002

0.11

250

TDS (mg/L)

9.1

4.70

6.71

6.01

500

Alkalinity (mg/L)

21.5

10.00

120

DO (mg/L)

0.30

3.50

12.80

8.90

BOD (mg/L)

0.05

1.57

25.60

0.30

(mg/L)

5.31

0.342

0.84

(mg/L)

0.09

0.009

0.68

(mg/L)

425.65

288.10

267.54

147.90

500

(mg/L)

1.07

10.41

4.108

31.7

(mg/L)

12.00

30.00

14.995

250

ND = Not Detected

Table 3 showing physicochemical parameters of Nnam river

Parameter

2013

2023

WHO

April

July

April

July

8.26

4.10

8.08

8.92

6.5-8.5

Electrical Conductivity (μs/cm)

7.83

12.08

17.82

19.03

250

Total Hardness (mg/L)

40.0

32.00

220.00

300

TSS (mg/L)

0.90

1.50

0.002

0.009

250

TDS (mg/L)

9.10

6.50

8.91

9.52

500

Alkalinity (mg/L)

20.0

12.00

120

DO (mg/L)

0.25

6.20

18.40

8.60

BOD (mg/L)

0.05

1.38

36.800

0.30

(mg/L)

9.40

0.31

0.510

0.55

(mg/L)

0.05

0.003

0.35

(mg/L)

329.5

123.5

144.15

148.17

500

(mg/L)

0.07

9.67

3.48

36.8

(mg/L)

7.2

17.00

4.998

9.99

250

ND = Not Detected

For a water source to be considered suitable for drinking and other domestic purposes, its WQI value must be less than 50. The

WQI values obtained in this study are shown in Table 4. The elevated WQI values for April obtained in all the rivers indicate that

the water quality at the various study locations in the first year is of very poor quality and deteriorated after 10years, therefore, is

unsuitable for human consumption and possibly domestic use. For July samples, only Ajali river shows some level of

deterioration after 10years. This could be as a result of agricultural activities around it. Generally, this water status report

unambiguously revealed that this body of water is being affected by anthropogenic activities in and around the river.

INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,

MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)

ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue V, May 2024

www.ijltemas.in Page 213

Table 4. WQI values for various samples

River

Year

Month

WQI

Water quality

Ajali

2013

April

72.93

Poor for drinking

July

47.34

Good for drinking

2023

April

425.33

Unsuitable for drinking

July

70.68

Poor for drinking

Karawa

2013

April

78.93

Very poor for drinking

July

85.79

Very poor for drinking

2023

April

194.16

Unsuitable for drinking

July

50.61

Poor for drinking

Nnam

2013

April

66.17

Poor for drinking

July

75.81

Very poor for drinking

2023

April

242.08

Unsuitable for drinking

July

62.95

Poor for drinking

IV. Conclusion

The results presented in this study highlight the general quality of water from Ajali, Karawa and Nnam rivers in Ezeagu local

government of Enugu state, Nigeria. The various significant physicochemical factors that have an

impact on the overall quality of river water were identified. A comparison of the physicochemical water parameters with their

respective permissible limits indicated that all but pH, DO and BOD were within the allowed permissible limits.

In the first year (2013), the water quality, as indicated by the WQI values (˂50), showed that only water from Ajali in July was

good for drinking. All the April samples very poor and deteriorated after 10 years as a result of pollution. The implication of the

results of this study is that water from the aforementioned rivers are currently unsuitable for drinking. Remediation strategies

need to be urgently put in place for continued use of this water source.

One way to achieve this is to stop untreated wastewater from entering the rivers.

References

1. Alum, O. L. and Okoye, C O. B. (2020). Pollution status of major rivers in an agricultural belt in Eastern Nigeria.

Environmental Monitoring and Assessment, 192(6), 393–. doi:10.1007/s10661-020-08366-3

2. APHA, 2012. Standard methods for the examination of water and wastewater. 21st edition. Washington, DC: American

Public Health Association (APHA), American Water Works Association (AWWA) and Water Pollution Control

Federation (WPCF). A

3. Barbosa, F. A. R., Callisto, M. and Galdean, N. (2016). The diversity of benthic macroinvertebrates as an indicator of

water and ecosystem health: A case study for Brazil. Aquatic Ecosystem Health and Management, 4(1), 51-59. https:

doi.org./10.1080/146349801757569270.

4. Bhutiani, R., Ahamad, F. and Ram, K. (2021). Quality assessment of groundwater at Laksar Block, Hardwar in

Uttarkhand, India using Water Quality Index: A case study. Journal of Applied and Natural Science, 13(1), 197- 203.

https:// doi.org /10. 31018 /jans.v13i1.2435.

5. Chauhan, A. and Singh, S. (2010) Evaluation of Ganga water for drinking purpose by water quality index at Rishikesh,

Uttarakhand, India. Report and opinion, 2(9): 53-61

6. Eaton, A.D., Clesceri, S.L., Rice, W.E., and Greenberg, A. E. (2005) Standard methods for the examination of water,

21st edition, pp. 15, 67.

7. Edwards, G. P., Molof, A. H., & Schneeman, R. W. (1965). Determination of orthophosphate in fresh and saline waters.

Journal of American Water Works Association, 57, 917–921.

8. Egun, N.K, and Oboh, I.P. (2022) Surface water quality evaluation of Ikpoba reservoir, Edo State, Nigeria. Int J Energy

Water Resour 6:509–519. https:// doi. org/ 10. 1007/ s42108- 021- 00139-z

9. Egun, N.K. and Ogiesoba-Eguakun, C.U. (2018) Physico-chemical and water quality index analysis of the Okhuaihe

River, Edo State, Nigeria. Afr J Aquat Sci 43(4):345–351

10. Ekhaise, F. O., and Anyasi, C. C. (2005). Influence of breweries effluent discharges on the microbiological and

physicochemical quality of Ikpoba River, Nigeria. Africa Journal of Biotechnology, 4(10), 1062–1065.

INTERNATIONAL JOURNAL OF LATEST TECHNOLOGY IN ENGINEERING,

MANAGEMENT & APPLIED SCIENCE (IJLTEMAS)

ISSN 2278-2540 | DOI: 10.51583/IJLTEMAS | Volume XIII, Issue V, May 2024

www.ijltemas.in Page 214

11. Ibrahim, A. E. M., Osman, B. O., and Mohamed-Ali, M. H. (2015). Assessment of Physicochemical parameters of

surface water sources in Kusti Town - Sudan. European Journal of Pharmaceutical and Medical Research, 2(4), 44 -58.

12. Iloba, K. I. (2021). Algal homogeneity in water and sediment of mid-Ethiope river, Nigeria: a response to severe

ecological disturbances. Global Nest Journal, 23, (1), 47- 56. https://doi.org/10.30955/gnj.003214

13. Iloba, K. I., Akawo, N.O and Godwin, P.I (2021). Assessment of Anwai river water quality using the weighted

arithmetic water quality index (WQI) in Delta State, Nigeria. Journal of Appllied and Natural Science, 13(3), 913 – 922.

https://doi.org/10.31018/jans.v13i3.2758

14. Murphy, J., and Riley, J. (1962). A modified single solution method for the determination of phosphate in natural

waters. Analytica Chimica Acta, 27, 31–36.

15. Nwabor, O., Forstinus, N., Emmanuel, I., Martins, P. E. and Ani O. C. (2016). Water and Waterborne Diseases: A

Review. International Journal of Tropical Disease & Health, 12(4), 1-14. Article no. IJTDH.21895 ISSN: 2278–1005,

NLM ID: 101632866.

16. Nwerem, J. O., Ejikeme, E. M., Ekere, N. R. and Ibeto, C. N. (2023). Statistical analysis of physiochemical properties

of Ajali river stretch in Enugu, Enugu state Nigeria. Journal of Chemical Society of Nigeria, 48(1).

https://doi.org/10.46602/jcsn.v48i1.851

17. Oboh, I.P. and Agbala, C.S. (2017) Water quality assessment of the Siluko River, southern Nigeria. Afr J Aquat Sci

42(3):279–286. https://doi. org/ 10. 2898/ 16085 914. 2017. 13715 79

18. Ogbu, K. C., Ebenebe, C. I., & Abajue, M. C. (2016). Physicochemical characteristics of Ama Brewery effluent and its

receiving Ajali River in Udi, Enugu State, Nigeria. Animal Research International, 13(2), 2392–2399.

19. Okoye, C. O. B., Ugwu, J. N., & Ibeto, C. N. (2009). Characterization of rural water resources for potable water supply

in some parts of Southeastern Nigeria. Journal of Chemical Society of Nigeria, 35(1), 83–87.

20. Otene, B. B. and Nnadi, P.C. (2019). Water Quality Index and status of Minichinda Stream, Port-Harcourt, Nigeria.

IIard International Journal of Geography and Environmental Management, 5(5), 2505-8221.

21. Otokunefor, T. V., and Obiukwu, C. (2005). Impact of refinery effluent on the physicochemical properties of a water

body in the Niger Delta. Applied Ecology and Environmental Research, 3(1), 61–72.

22. Seiyaboh, E.I., Izah, S.C. and Oweibi, S. (2017) Assessment of water quality from Sagbama Creek, Niger delta,

Nigeria. Biotechnol Res 3(1):20–24

23. Smith, R. K. (1999). Hand-book of environmental analysis (4th ed.p. 237). Canada: Genium Publishing Company.

24. Smith, W.S., Silva, F. L. and Biagioni, R. C. (2019). River dredging: when the public power ignores the causes,

biodiversity and science. Ambiente & Sociedade n São Paulo, 22, 22. e00571. https://doi.org/10.1590/1809-4422asoc

007r1vu19L1AO

25. Thakor, F.J., Bhoi, D.K., Dabhi, H.R., Pandya, S.N and Chauhan, N.B. (2011). Water quality index (W.Q. I) OF Pariyej

Lake Dist.kheda-Gujarat. Current World Environment, 6 (2): 225-231.

26. Tyagi, S., Sharma, B., Singh, P. and Dobhal, R. (2013) Water quality assessment in terms of water quality index. Am J

Water Resour 1(3):34–38

27. UN-waters. (2016). Towards a Worldwide Assessment of Freshwater Quality: A UN-water Analytical Brief. pp. 40.

28. World Health Organization (2017). Guidelines for drinking water quality. World Health Organization (WHO). First

Addendum to the 4th edition. ISBN 9789241548151. Pp. 564.

29. Zakir, H. M., Sharmin, S., Akter, A. and Rahman, M. S. (2020). Assessment of health risk of heavy metals and water

quality indices for irrigation and drinking suitability of waters: a case study of Jamalpur Sadar area. Bangladesh

Environmental Advances, 2, 100005. doi.org/10.1016/ j. envadv.2020.100005.