Physical and Chemical Scrutiny of Obizi River in Awka South Local Government Area of Anambra State, Nigeria for Domestic Consumption

E. C. Nwanna; L. C. Orakwe; E. C. Chukwuma; C. P. Nwachukwu; C. D. Okpala; J. I. Maduegbuna; H. C. Oyeoka

doi:10.9734/jerr/2024/v26i21080

Physical and Chemical Scrutiny of Obizi River in Awka South Local Government Area of Anambra State, Nigeria for Domestic Consumption

Full Article - PDF Review History

Published: 2024-02-06

DOI: 10.9734/jerr/2024/v26i21080

Page: 170-180

Issue: 2024 - Volume 26 [Issue 2]

E. C. Nwanna *

Department of Agricultural and Bioresources Engineering, Nnamdi Azikiwe University Awka, Nigeria.

L. C. Orakwe

Department of Agricultural and Bioresources Engineering, Nnamdi Azikiwe University Awka, Nigeria.

E. C. Chukwuma

Department of Agricultural and Bioresources Engineering, Nnamdi Azikiwe University Awka, Nigeria.

C. P. Nwachukwu

Department of Agricultural and Bioresources Engineering, Nnamdi Azikiwe University Awka, Nigeria.

C. D. Okpala

Department of Agricultural and Bioresources Engineering, Nnamdi Azikiwe University Awka, Nigeria.

J. I. Maduegbuna

Department of Agricultural and Bioresources Engineering, Nnamdi Azikiwe University Awka, Nigeria.

H. C. Oyeoka

Department of Polymer and Textile Engineering, Nnamdi Azikiwe University Awka, Nigeria.

*Author to whom correspondence should be addressed.

Abstract

The Obizi River in the Awka South Local Government Area of Anambra State was examined physically and chemically to evaluate its contamination level and suitability for home use. It is important for recreational, fishing, cooking, drinking, and other applications. Its typical applications for drinking, cooking, fishing, recreational activities and other uses are limited since it flows through a canal that might be contaminated by industrial, agricultural, and other human activities. Nitrate mg/l, nitrite mg/l, magnesium mg/l, zinc mg/l, total dissolved solid (TDS) mg/l, hardness mg/l, sulphate mg/l, phosphate mg/l, alkalinity mg/l, acidity mg/l, sodium mg/l, biological oxygen demand (BOD) mg/l, chemical oxygen demand (COD) mg/l, total suspended solid (TSS) mg/l, TS mg/l, oxygen demand (OD) mg/l, and potassium mg/l are among the parameters that were evaluated. Total dissolved solids (TSS) were calculated as the difference between total solids and total dissolved solids. The zinc and nitrate elements within the samples were measured using the ultraviolet (UV) VIS spectrophotometric method. Sulphate was determined turbidimetrically by the absorption spectrophotometry. Magnesium content, total hardness, and alkalinity were measured through titration. TDS (mg/L) was measured with a Multi-Meter (HI 991300, Hanna Equipments, Romania), potassium and sodium ions were assessed by flame photometric technique, chemical oxygen demand (COD) was identified photometrically using the SpectroQuant Nova 60 COD cell test (Merck) in the range of 10 – 150 mg/L. Biological oxygen demand (BOD) was determined using the OxiDirect BOD system and total suspended solids (TSS) was calculated as the difference between total solids and total dissolved solids. Phosphates were measured using the ascorbic acid method, total solids were estimated gravimetrically, and oxygen demand (OD) was measured on-site using a dissolved oxygen meter JENWAY-3405 (Manufacturer: Barloworld Scientific Ltd., England). To find out if the results were significant or not, the parameters were subjected to an ANOVA single factor analysis. The analysis's conclusion was that the data were statistically not significant. Since nitrate and OD were above the World Health Organization's (WHO) limit while most other physicochemical parameters were below it, the ANOVA result showed that there was no significant difference between the physicochemical characteristics of the water samples. With the exception of nitrite and OD, which are above the WHO limit for domestic drinking water and other purposes, it was discovered that the majority of the physicochemical parameters fell within the organization's water quality standards for these purposes. As a result, the water quality is not good and should not be drunk unless treated.

Keywords: Physical and chemical scrutiny, obizi river, ANOVA, water quality, drinking purpose

How to Cite

Nwanna, E. C., Orakwe, L. C., Chukwuma, E. C., Nwachukwu , C. P., Okpala , C. D., Maduegbuna, J. I., & Oyeoka , H. C. (2024). Physical and Chemical Scrutiny of Obizi River in Awka South Local Government Area of Anambra State, Nigeria for Domestic Consumption. Journal of Engineering Research and Reports, 26(2), 170–180. https://doi.org/10.9734/jerr/2024/v26i21080

Downloads

Download data is not yet available.

References

Duressa G, Assefa F, Jida M. Assessment of bacteriological and physicochemical quality of drinking water from source to household tap connection in Nekemte, Oromia, Ethiopia. Journal of Environmental and Public Health 2019, 1–7.

Muhamme AU, Nicolas G, Joachim VB. Impact of Drinking Water Quality and Sanitation Behavior on Child Health: Evidence from Rural Ethiopia, ZEF–Discussion Papers on Development Policy No. 221, Center for Development Research, Bonn, Germany; 2016.

Grady CA, Kipkorir EC, Nguyen K, Blatchley II ER. Microbial quality of improved drinking water sources: evidence from western Kenya and southern Vietnam. Journal of Water and Health. 2015;13(2):607–612.

Bisi-Johnson MA, Adediran KO, Akinola SA, Popoola EO, Okoh AI. Comparative physicochemical and microbiological qualities of source and stored household waters in some selected communities in southwestern Nigeria. Sustainability. 2017;9(3):454.

Gonçalve N, Valente T, Pamplona J. Water supply and access to safe water in developing arid countries. SdrP Journal of Earth Sciences & Environmental Studies, 2019;4(2):589–599. Available:Https://Doi.Org/10.25177/Jeses.4.2.Ra.497

Unesco, World Water Assessment Programme (United Nations), & UN-Water. Leaving no one behind: The United Nations World Water Development Report; 2019.

WHO. World Health Organization guideline for drinking water quality. 3rd Edn., World Health Organization, Geneva, Switzerland; 2011.

World Health Organization, UNICEF, & WHO/UNICEF Joint Water Supply and Sanitation Monitoring Programme. (2015). 25 years progress on sanitation and drinking water: update and MDG assessment; 2015.

Mkwate R, Chidya RCG, Wanda EMM. Assessment of drinking water quality and rural household water treatment in Balaka District, Malawi. Physics and Chemistry of the Earth, Parts A/B/C, 2017;100:353–362. Available:https://doi.org/10.1016/j.pce.2016.10.006

Ezenwaji EE, Awopeju AK, Otuti VI, Edupta BM. Spatial Patterns of Residential Water Supply Accessibility Levels in Anambra State, Nigeria. Journal of Engineering Research and Applications. 2014;4(1):326336.

APHA Standard Methods for the Examination of Water and Wastewater. 21st Edn., American Public Health Association/American Water Works Association, Washington, DC., USA; 2005.

Gayathri S, Latha N, Ramachandra Mohan M. Impact of climate change on water quality of Shoolkere Lake, Bangalore. Journal of Academia and Industrial Research. 2014; 2(6):362-367.

Ehiagbonare JE, Ogunrinde YO. Physico-chemical analysis of fish pond water in Okada and its environs, Nigeria. African J. Biotechnol. 2010:9(36).

Saidu MA, Gimba BE. Analysis of Physicochemical parameters of selected Open-Wells in Southern Senatorial Zone of Kaduna State, Nigeria. FUDMA Journal of Sciences. 2019;3(1):39–48.

Manivaskam N, Physicochemical examination of water sewage and industrial effluent, 5th Ed. Pragati Prakashan Meerut; 2005.

Mahananda HB, Mahananda MR, B.P. Mohanty, Studies on the physico-Chemical And Biological Parameters Of A Fresh Water Pond Ecosystem as an Indicator of Water Pollution. Ecol. Env & Cons.11(3-4), 2005, pp 537-541.

James ME. Water Quality and Recalculating Aquaculture Systems. Aquaculture Systems Technologies, LLC. New Orleans, LA. 2000;149:16-17.

Obinna C. Nigeria May Miss MDGS Target for U.N.I.C.E.F Water, Sanitation. Vanguard Newspaper (8/8 2014); 2014. Available:www.vanguardng.com