Assessment of Nitrate Occurrence in the Shallow Groundwater of Merimandroso Area, Analamanga Region, Madagascar Using Multivariate Analysis

Mamiseheno Rasolofonirina; Voahirana Ramaroson; Solofonirina Dieudonné Ravelomanantsoa

American Journal of Water Resources. 2018, 6(1), 39-47
DOI: 10.12691/AJWR-6-1-5

Original Research

Assessment of Nitrate Occurrence in the Shallow Groundwater of Merimandroso Area, Analamanga Region, Madagascar Using Multivariate Analysis

Mamiseheno Rasolofonirina^1,, Voahirana Ramaroson^{1, 2} and Solofonirina Dieudonné Ravelomanantsoa¹

¹Department of Physics, Faculty of Sciences, University of Antananarivo, Antananarivo, Madagascar

²Department of Isotope Hydrology, INSTN-Madagascar, Antananarivo, Madagascar

Pub. Date: April 13, 2018

Full Text PDF

Cite this paper

Mamiseheno Rasolofonirina, Voahirana Ramaroson and Solofonirina Dieudonné Ravelomanantsoa. Assessment of Nitrate Occurrence in the Shallow Groundwater of Merimandroso Area, Analamanga Region, Madagascar Using Multivariate Analysis. American Journal of Water Resources. 2018; 6(1):39-47. doi: 10.12691/AJWR-6-1-5

Abstract

Knowing the groundwater quality is important for the drinking water supply in the highland area of Madagascar, including Merimandroso Commune insofar that groundwater is the main source of drinking water for a large number of Malagasy people. In this way, this study assessed the shallow groundwater quality with special focus on nitrate occurrence using multivariate statistical techniques such as cluster analysis (CA) and principal component analysis (PCA). That was to determine the similarities among the water samples in terms of hydrochemical features and to identify the different mechanisms involved in the shallow groundwater hydrochemistry. The study was conducted on twenty-one water samples collected from dug wells. Cluster analysis grouped the water-sampling points into two main clusters: a highly nitrate polluted group (concentration greater than 50 mg/l) and a non-nitrate polluted group. The results showed a spatial variation of the groundwater chemistry processes, while no such variability was found temporally for water samples collected at different periods. Principal component analysis extracted three principal components accounted for over 82% of the total variance. It attributed the hydrochemical features of the water samples of high nitrate content to the nitrate pollution mechanisms along with the weathering of feldspar and ferromagnesian minerals. For some of the latter water samples, the water chemistry is likely affected by igneous rock weathering. This study confirmed both the usefulness and powerfulness of multivariate statistical techniques in water quality assessment, since they helped get a proper understanding of processes controlling the shallow groundwater chemistry.

Keywords

assessment, groundwater quality, nitrate, cluster analysis, principal component analysis

Copyright

This work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References

[1]	World Health Organization (WHO), Global Health Observatory Data Repository. Estimates for 2000 – 2012. Geneva. 2012.

[2]	World Health Organization (WHO), Guidelines for Drinking Water Quality (4th ed.). Geneva. 2011.

[3]	Agency for Toxic Substances and Disease Registry (ATSDR), Nitrates and Nitrites. CAS # 84145-82-4, 14797-65-0. Atlanta, GA: U.S. Department of Public Health and Human Services, Public Health Service. [Online]. [Online] Available at http://www.atsdr.cdc.gov/toxfaqs/tfacts204.pdf. [Accessed Aug. 10, 2017]

[4]	Knobeloch, L., Salna, B., Hogan, A., Postle, J. and Anderson, H., “Blue babies and nitrate-contaminated well water”, Environ Health Perspect, 2000, 108, 675-678.

[5]	Mueller, D.K., Hamilton, P.A., Helsel, D.R., Hitt, K.J., and Ruddy, B.C., Nutrients in ground water and surface water of the United States--an analysis of data through 1992: U.S. Geological Survey Water-Resources Investigations Report 95-4031, 74 p. 1995.

[6]	Dylan, B., Aaron, K., Giorgos, K., Katherine, L., Megan, M., Graham, E. F. and Thomas, H., Groundwater Nitrate Occurrence: Technical Report 4, 2012.

[7]	Tredoux, G. and Talama, A. S., Groundwater Pollution in Africa. Nitrate Pollution of groundwater in southern Africa, Ed. Taylor&Francis/Balkema, 15-36. 2006.

[8]	Staudt, M., Environmental Hydrogeology of Ramotswa. Report by the Environmental Geology Division, 47 p., Dept of Geological Survey (DGS), Lobatse, Botswana. 2003.

[9]	Smedley, P.L., Groundwater Quality: Madagascar. British Geological Survey.NERC 2002. [Online]. [Online]. Available at http://www.bgs.ac.uk/sadcreports/madagascar2002smedleybgsgroundwaterquality.pdf. [Accessed Oct. 5, 2016]

[10]	Rasolofonirina, M., Ramaroson, V., Raoelina Andriambololona, “On-site Sanitation Influence on Nitrate Occurrence in the Shallow Groundwater of Mahitsy City, Analamanga Region, Madagascar”, Environment and Pollution, 2015, 4(2), 55-65.

[11]	Varol, M., Gökot, B., Bekleyen, A. and Şen, B., “Spatial and Temporal Variations in Surface Water Quality of the Dam Reservoirs in the Tigris River Basin, Turkey”, Ca- tena, 2012, 92, 11-21.

[12]	Kazi, T.G., Arain, M.B., Jamali, M.K., Jalbani, N., Afridi, H.I., and Sarfraz, R.A., “Assessment of water quality of polluted lake using multivariate statistical techniques: A case study”, Ecotox Environ Safe, 2009, 72, 301-309.

[13]	Andrade, E. M., Palácio, H. A. Q., Souza, I. H., Leão, R. A. and Guerreiro, M. J., “Land Use Effects in Groundwater Composition of an Alluvial Aquifer (Trussu River, Brazil) by Multivariate Techniques”, Environmental Research, 2008, 106(2), 170-177.

[14]	Usman Nasiru Usman, Mohd Ekhwan Toriman, Hafizan Juahir, “Assessment of Groundwater Quality Using Multivariate Statistical Techniques in Terengganu”, Science and Technology, 2014, 4(3), 42-49.

[15]	Adebola, A. Oketola, S. M., Adekolurejo, Oladele Osibanjo, “Water Quality Assessment of River Ogun Using Multivariate Statistical Techniques”, Journal of Environmental Protection, 2013, 4, 466-479.

[16]	UN. Madagascar. In: Groundwater in Eastern,Central and Southern Africa, Natural Resources/Water Series No. 19, United Nations, New York, 1989, 133-149.

[17]	Besairie, H., “Précis de géologie malgache”, Annales géologiques de Madagascar, 1973, 36, 109-134.

[18]	Goncalves, P., Nicollet, C., and Lardeaux, J. M, “Finite strain pattern in Andriamena unit (North Central Madagascar): evidence for late Neoproterozoic-Cambrian thrusting during continental convergence”, Precambrian Research, 2003, 123, 135-157.

[19]	Jeffrey, D., Hydrogeological mapping of north central of Madagascar using limited data, 2009. [Online]. [Online]. Available at http://nora.nerc.ac.uk/id/eprint/9062. [Accessed Sept. 25, 2015].

[20]	Grillot, J-C and Ferry, L., “Approche des échanges surface-souterrain en milieu cristallin altéré aquifère”, Hydrol. Continent, 1990, 5(1), 3-12.

[21]	Grillot, J. C., Blavoux, B., Rakotondrainibe, J. H., Raunet, M., and Randrianarisoa, N., “A propos des aquifères d'altérites sur les hauts plateaux cristallophylliens de Madagascar”, Comptes Rendus de L'Académie des Sciences Paris Hydrogéologie, 1987, 305(Série II), 1471-1476.

[22]	Brian, S. Everitt, Landau, S., Leese, M. and Stahl, D., Cluster Analysis, 5th Edition. John Wiley & Sons, Ltd. 2011

[23]	Shrestha, S. and Kazama, F., “Assessment of surface water quality using multivariate statistical techniques: A case study of the Fuji River basin, Japan”, Environ. Model. Softw, 2007, 22, 464-475.

[24]	Wang, Y., Wang, P., Bai, Y., Tian, Z., Li, J., Shao, X., Mustavich, L.F. and Li, B.-L., “Assessment of surface water quality via multivariate statistical techniques: A case study of the Songhua River Harbin region, China”, J. Hydro-Environ. Res., 2013, 7, 30-40.

[25]	Zhaoa, Y., Xia, X.H., Yang, Z.F. and Wang, F., “Assessment of water quality in Baiyangdian Lake using multivariate statistical techniques”, Procedia Environmental Sciences, 2012, 13, 1213-1226.

[26]	Huang, F., Wang, X., Lou, L., Zhou, Z. and Wu, J., “Spatial variation and source apportionment of water pollution in Qiantang River (China) using statistical techniques”, Water Res., 2010, 44, 1562-1572.

[27]	Ryberg, K.R., Cluster Analysis of Water-Quality Data for Lake Sakakawea, Audubon Lake, and McClusky Canal, Central North Dakota, 1990-2003. U.S. Geological Survey Scientific Investigations Report 2006-5202, 38 p. 2006.

[28]	Abdi, H. and Williams, Lynne J., Principal component analysis. John Wiley & Sons, Inc. Vol.2. 2010.

[29]	Kaiser, H.F., “The application of electronic computers to factor analysis”, Educational and Psychological Measurement, 1960, 20, 141-151.

[30]	Dinicola, R.S., Continued biodegradation of chloromethane compounds in ground water at Operable Unit 1, Naval Undersea Warfare Center, Division Keyport, Washington. U.S. Geological Survey Scientific Investigations Report 2006-5056, 42 p. 2006.

[31]	Rasolofonirina, M., Ramaroson, V. and Ravelomanantsoa, S.D., “Use of Cluster Analysis Technique for Water Quality Assessment in Mahitsy Commune, Central Highland of Madagascar”, Int J Recent Sci Res. 2018, 9(1). 23191-23196.

[32]	Kaiser, H F and Rice, J., “Little Jiffy, Mark IV,” Educational and Psychological Measurement, 1974, 34(1), 111-117.