Evaluation of Soil Water Characteristic Curves of Boron added Sand-bentonite Mixtures using the Evaporation Technique
Article Sidebar
Main Article Content
Abstract
Compacted bentonite or sand-bentonite mixtures are considered buffer/backfill materials in the engineering barriers of deep geological repositories for high-level nuclear waste (HLW) disposal in many countries. The design and long-term functionality of nuclear repositories have critical importance for environmental safety and public health. The initially unsaturated buffer material could become re-saturated long after following the sealing of the repository. Although the saturation degree of the buffer might decrease due to high temperatures and evaporation, it tends to increase with groundwater intrusion. Therefore, the soil water characteristic curves (SWCCs) for these unsaturated soils are a key factor in geotechnical engineering. Yet, the determination of SWCCs can be time-consuming and prone to inaccuracies. The HYPROP (Hydraulic Property Analyzer) evaporation technique is a preferred method for accurately determining water retention curves of soils. This reliable method was applied to estimate the water retention curves for sand-bentonite mixtures in the presence of boron minerals. Known for their minimal thermal expansion and commonly used in various industries, boron minerals may improve the thermal stability of sand-bentonite mixtures. The findings revealed that the boron addition increased the water retention capacity of the 10% bentonite mixtures but had a negligible impact on the 20% bentonite mixtures.
Article Details
Copyright (c) 2024 Alpaydin SG, et al.
This work is licensed under a Creative Commons Attribution 4.0 International License.
Rahman A, Islam M, Ahmed F. Physico-chemical and bacteriological analysis of drinking tube-well water from some primary schools, Magura, Bangladesh to evaluate suitability for students. International Journal of Applied Sciences and Engineering Research. 2015; 4: 5.
Murray CJ, Lopez AD. Alternative projections of mortality and disability by cause 1990-2020: Global Burden of Disease Study. Lancet. 1997 May 24;349(9064):1498-504. doi: 10.1016/S0140-6736(96)07492-2. PMID: 9167458.
Rout C, Sharma A. Assessment of drinking water quality: A case study of Ambala cantonment area, Haryana, India. International Journal of Environmental Sciences. 2011; 2: 2.
LaSota DE, Bidlack TW, Evans JW. Laboratory Manual for the Microbiological Analyses of Public Drinking Water. OhioEEPA. 2001.
Mohammed FAl, Mutasher A. Application of Water Quality Index for Evaluation of Groundwater Quality for Drinking Purpose in Dibdiba Aquifer, Kerbala City, Iraq. Journal of Babylon University/Engineering Sciences. International Conference on Water and the Environment: Development Issues for the 2lst century. 1992, Dublin, Ireland. 2013. 5:21.
Yves L. editor. WHO, author. Minimizing potential for changes in microbial quality of treated water. London, UK: IWA Publishing. 2004.
Kwame MM. Assessment of Drining water Quality in EHI Community in the Ketu- North District of the Volta Region of Ghana. Department of Theoretical and Applied Biology, Kwame Nkrumah University of Science and Technology, Kumasi, Ghana in Partial Fulfillment of the Requirements for The Degree of Master of Environmental Science. 2011.
Meybeck M, Helmer R. Introduction in: Water Quality Assessments. A Guide to the Use of Biota, Sediments and Water in Environmental Monitoring. 2nd edition. Chapman & Hall, London. 1996.
Mohsin M, Safdar S, Asghar F, Jamal F. Assessment of Drinking Water Quality and its Impact on Residents Health in Bahawalpur City. International Journal of Humanities and Social Science. 2013; 3: 15.
Haydar CM, Tarawneh K, Nehme N, Amaireh M, Yaacoub A, Diab W. Heavy metals content in water and sediments in the upper Litani River Basin, Lebanon Journal of Geoscience and Environment Protection. 2022; 10: 7; 139-158.
C Haydar, N Nehme, S Awad, B Koubayssi, M Fakih, A Yaacoub, Physiochemical and microbial assessment of water quality in the Upper Litani River Basin, Lebanon, J Environ Earth Sci. 2014; 4 (9): 87-97.
Nehme N, Haydar C, Koubaissy B, Fakih M, Awad S, Toufaily J, Villieras F, Hamieh T. Metal concentrations in river water and bed sediments of the Lower Litani River.2014.
Nehme N, Haidar CM, Dib A, Azouj N, Tarawneh K. Quality Assessment of Groundwater in the lower Litani Bassin (LLRB), Lebanon. Geosciences Research. 2020; 5: 1.
Nehme N, Haidar CM, Diab W, Tarawneh K, Villieras F. 2019Assessment of Heavy Metal Pollution in the sediments of the Lower Litani River Basin, Lebanon.Jordan Journal of Earth and Environmental Sciences JJEES. 2019; 10 (2): 104-112. ISSN 1995-6681.
N Nehme, CM Haidar, M Rammal, F Abou Abbas, H Rammal, N Al Ajouz2021, Study of the water assessment in the Alhoujair valley in Lebanon. J. Mater. Environ. Sci. 2021; 12 (11): 1392-1404.
Gautam SP. Water and Wastewater Analysis. Control Pollution Control Board.
Guidelines for Drinking-Water Quality: Fourth Edition Incorporating the First Addendum. Geneva: World Health Organization; 2017. PMID: 28759192.
WHO. World Health Report 1999. World Health Organization. Geneva. 1999.
Ministry of Health (MoH). Strategic Plan 2013-2016 Non-Communicable Diseases and Their Risk Factors. Version 1, Ministry of Health, Lusaka. 2013.
Mulugeta S. Assessment of Drinking Water Quality in Mercato, Addis Ababa. Department of Civil Engineering Addis Ababa University. 2012.
Sanches SM, Muniz JM, Passos C, Vieira EM. Chemical and microbiological analysis of public school water in Uberaba Municipality. Ambiente and Agua Journal of applied science. 2015.
Suk WA, Ruchirawat KM, Balakrishnan K, Berger M, Carpenter D, Damstra T, de Garbino JP, Koh D, Landrigan PJ, Makalinao I, Sly PD, Xu Y, Zheng BS. Environmental threats to children's health in Southeast Asia and the Western Pacific. Environ Health Perspect. 2003 Aug;111(10):1340-7. doi: 10.1289/ehp.6059. PMID: 12896856; PMCID: PMC1241616.
Tay C. Report on the Ground Water Quality of Akatsi and Ketu Districts in the Volta Region of Ghana. CSIR – WRI. 2004.
WHO Regional Office for Europe. Sodium, Chlorides, and Conductivity in Drinking Water, A Report on A WHO Working Group. Copenhagen, EURO Report and Studies 2. 1978.
WHO, author. Drinking-water Quality Standards, Objectives and Guidelines Technical Support Document for Ontario Drinking Water Standards, Objectives and Guidelines June 2003. Ministry of Environment; 2003.
World Bank. Republic of Lebanon - Water sector: public expenditure review. Public expenditure review (PER). Washington, DC: World Bank. 2010.
World Health Organization (WHO). International Standards for Drinking Water, Geneva. 1958.
World Health Organization (WHO). Guidelines for Drinking Water Quality, Genève: World Health Organization, 2nd ed. 1996.
World Health Organization (WHO). Guideline for Drinking Water Quality, Health criteria, 2nd ed., 2. 1997.
World Health Organization (WHO). Guidelines for Drinking Water Quality, Genève: WHO Press, 4th ed. 2011.
World Health Organization (WHO). Water and sanitation. World Health Organization Regional Office. 2013.
Maruthi YA, Hossain K, Goswami A. Assessment of drinking water quality in some selected primary schools in Visakhapatnam. Pelagia Research Library. 2012; 3(5):1071-1074. www.pelagiaresearchlibrary.com
Napacho ZA, Manyele SV. Quality assessment of drinking water in Temeke District (part II): Characterization of chemical parameters. African Journal of Environmental Science and Technology. 2010; 4(11): 775-789. http://www.academicjournals.org/AJEST