Abstract
In Upper Egypt, the settled areas were constructed on the flood plain clayey soils which situated on both sides of River Nile course. These clayey sediments are consisting of silts, clays and sands with average values of 47.4, 40.3 and 12.3% respectively and classified as inorganic clays (CL). The clay mineral composition of these inorganic clayey soils constitutes of montmorillonite, kaolinite, illite–montmorillonite mixed layer and minor percents of chlorite and illite. These populated old cities were extended during last three decades in the same time the sewage networks are not found in new extended areas. So that, the private sector was forced to storage wastewater in so called wastewater-tanks below or near the houses. These tanks sometimes filled completely or broken then the wastewater which rich in organic matter will saturate the clayey soils. The wastewater had been caused an increasing in original plasticity and swelling potentiality of these clayey soils. So that, serious damages such as wall cracks and foundation tilting were observed.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Background
In Egypt, mostly the populated area was constructed over areas covered with flood plain clayey soils which concentrated on both sides of River Nile course and its two branches in the Delta Governorates. These clayey sediments of River Nile floodplain region were deposited during pre-construction of the High Dam. The average thickness of these clayey sediments is 10 m between Aswan and Cairo. These sediments are covered about 4.6 of the total area of Egypt and are characterized by low strength and high compressibility [3].
Mostly, the actual damage to structures due to swelling clayey-soils caused from attracts and absorbs water then swells. The main source of this water is drinking water or wastewater when these lines were broken. In Upper Egypt, the intense increase of population has created a critical need to expand dwelling areas besides the old cities were constructed by the private sector. The absence of a network of sewage in some places and the existence of the so-called tanks for sewage down or near houses considered a serious problem especially when these tanks are broken or filled with wastewater. The wastewater will be absorbed by permeable clayey-soil. This will cause increasing in its natural swelling ability owing to richness of wastewater with organic matter which increases plasticity and swelling potentiality of these clayey-soils. Accordingly, a lot of geotechnical problems in these constructions such as horizontal and diagonal wall cracks and sometimes foundation tilting were recorded (Fig. 1).
Damage and foundation movements caused by expansive clayey soils usually gradually occurred and do not cause rapidly hazardous effects such as hurricanes and earthquakes but often they are much worse, even causing major structural distress [20]. The present study aims to evaluate the hazardous effects of wastewater on plasticity and swelling potentiality of clayey soil and extended its impact on buildings which were built on this soil.
Location and geologic setting
The studied area is a part of the Nile flood plain of Upper Egypt and extends between latitudes 32°20¯ and 32°15¯ E and longitudes 26°10¯ and 26°45¯ N (Fig. 2). The geology of the study area can be summarized as followings:
-
1.
Lower Eocene carbonates are the most famous and widely distributed rock units in Sohag Governorate, Upper Egypt. Lithologically and paleontological, the Lower Eocene sequences can be subdivided into two rock formations; Thebes and Drunka formations.
-
a.
Thebes formation was first introduced by Said [36]. It is represented by thick bedded and laminated limestone succession with flint bands.
-
b.
Drunka formation overlies the Thebes formation and it is easily differentiated by its snowy white colour and massive bedding. As well as, it covers more than 90% of the area around Sohag Governorate [29].
-
a.
-
2.
Madmoud formation [34, 35] represents the Early Pliocene transgression of the Mediterranean Sea and filling of the Nile canyon.
-
3.
Issawia Formation of the Early Pleistocene [28, 34, 35] crops out along the margins of the Eocene escarpment. It consists of hard red breccias reaching about 10 m in thickness and its breccia clasts ranging from 0.3 to 3 m in diameter [29].
-
4.
Armant formation (Early Pleistocene, [34, 35]) represents in the studied area as coarse-grained sediment terraces of alluvial fans at different heights unconformably overlying Eocene succession. Both Issawia and Armant formations are laterally inter-tonguing [28].
-
5.
Qena formation [35] exhibits low-topographic hills and consists of a thick succession of sand-gravel association. West of Sohag Governorate, many quarries exploit Qena Formation for construction purposes [2].
-
6.
Abbassia formation [34, 35] is represented by a gravel sequence overlying the Qena Formation on both banks of the River Nile.
-
7.
Dandara formation [35] occurred closer to the cultivated lands and is presented by sand and silt intercalations.
-
8.
Flood plain (cultivated lands) is are mainly restricted to the narrow tract of the River Nile Valley.
-
9.
Recent Wadi Deposits are varying greatly in both the thickness and texture depending on the land morphology and the intensity and regime of the flashflood events forming them [33].
Methodology and test procedures
Forty undisturbed and disturbed samples were collected from four boreholes (I: Tahta, II: Sohag, III: Akhmim and IV: Aulad Toq Sharq, Figs. 2, 3). These samples were immediately covered by wax in situ and kept in a cool place for short period until were used in different tests. The initial moisture water content was determined by heating to 110 °C for 24 h according to ASTM D 2216 [11]. Specific gravity determined according to ASTM 854 [13]. The total organic matters (TOM) of both soil samples and wastewater were calculated by using ignition methods according to ASTM D 2974 [10]. The grain size analysis (gradation) of soil samples was done according to ASTM C136 [9]. The consistency limits (liquid, plastic limits and plasticity index) were done according to ASTM D4318 [12] for both tap water and wastewater treatments. Consequently, swelling behavior of the studied soil samples (swelling pressure and swelling percentage) was done by using odeometer testing [8] for both tap water and wastewater treatments. Also, the free swelling was carried out according to Holtz and Gibbs [26]. The chemical analysis was done by standard methods [18] to determine the exchangeable cations (Na+, K+, Ca2+ and Mg2+) for both tap water and wastewater treated soil samples. X-ray diffraction of <0.2 μm was done for representative samples. All above tests (except grain size analysis and X-ray) were done for both the original soil samples and wastewater treated soil samples after soaking in wastewater for 10 weeks.
Results and discussion
The obtained data of physical properties of the studied soils as well as the effect of wastewater on their plasticity, cation exchange capacity and swelling potentiality will be used in the studied soil classification as the followings:
Grain size
The grain size distribution of clayey sediments plays a vital factor effecting on their swelling potential. The amount of swelling of clayey-sediments increases by increasing the amount of clay-size (<0.002 mm) materials, that due to increasing the specific surface area of these materials. Based on grain size distribution, the soil sequence in the studied area can be subdivided into distinct three units (A, B and C, Fig. 3).
The studied soil samples are predominantly by more or less smoothed grading curves that produce a considerable amount of voids between their particles (Fig. 4). The studied soil samples are consisting of silts, clays and sands with average values 47.4, 40.3 and 12.3%. Furthermore, the studied soil samples were classified as inorganic clays of medium plasticity, sandy/silty/lean clays (CL).
Dry density
The dry density of soil greatly affects volume changes. The initial dry density of the studied soil samples fluctuates from 1.833 to 1.993 gm/cm3 but the dry density of wastewater treated soil samples ranges from 1.795 to 1.965 gm/cm3 (Table 1; Fig. 5). It is found that, the dry density of the studied soil samples decreases when soil samples treated with wastewater which rich in organic matter. This observation agrees with many researchers (e.g. [17, 32, 25]).
Clay mineralogy
Both mineral constitutes and clay-sized fractions of fine-grained soil influence its cation exchange capacity, plasticity and swelling potentiality. Generally, the basal spacing of the 2:1 clay minerals influences greatly on plasticity of the clayey soil. The larger the basal spacing of clay mineral species the higher its water adsorption capacity [7, 15, 37]. The water adsorption capacity of smectite-group is larger than kaolinite group owing to its different structure and its greater capacity of water adsorption [16].
The clay minerals composition of fine-grained soil is likely to be the most important controlling factor for many properties and knowledge of the composition may thus simplify problems. Figure 6a shows X-ray diffraction pattern of the studied soil and indicating that montmorillonite (52%), kaolinite (26%) and illite–montmorillonite mixed layer (12%) are the most predominant clay mineral species in all samples. Chlorite (8%) and scarce amount of illite (3% Table 1; Fig. 6a, b) are recorded.
Initial moisture content
Geotechnically, the moisture water content of and fine-grained soil plays a very effective regulation in its capability to expand. The variation in moisture water content of clayey soil causes severe damage to the overlying structures [14, 40, 42–45]. When clayey-rich fine-grained soils are wet, the negatively charged surfaces of 2:1 clay minerals attract positively charged water molecules causing expansion of clay structure. The variation in moisture content is one of the most important factors affecting volume change of dry clayey-rich soil. The thickness of the unit cell structure of clay mineral is relatively small but when moisture water is absorbed into this structure, its thickness increases. The moisture water content of the studied soil samples varies from 5.4 to 13.7% (Table 1).
Consistency limits
From geotechnical point of view, the clayey-soil samples are not classified on the basis of grain size distribution, but according to their plasticity and compressibility. The plasticity characteristics of fine-grained soil are used as fundamentals in classification processes and indirect quantification of soil swell potential. The consistency limits were used as important indicators of engineering behavior and are correlating with the engineering properties of fine-grained soils [24].
The original liquid limit of the studied soil samples is ranging from 39 to 63%, but the liquid limit of wastewater treated soil samples is varying from 66 to 82% (Table 2). That means the soil samples plasticity was increased when treated with wastewater and transformed from clays of medium plasticity (CL) into organic clays of high plasticity (CH, Fig. 7a). The plasticity index of the wastewater treated soil samples is ranging from 34 to 53% (Table 2), so these clayey soils will behave as very high swelling capabilities [19].
Consequently, based on the plasticity index (PI) and clay content (%) values in the Williams [39] chart, the studied flood plain soil samples lie in field of medium exρpansion whereas the wastewater treated soil samples lie in high expansion field (Fig. 7b). The modifications which were took placed in the initial consistency limits of the studied soil samples owing to increasing of organic matters which absorbed from wastewater.
Cation exchange capacity (CEC)
The clayey-rich soils usually carry negative charges these charges owing to occurrence clay particles and organic materials. These negatively charges due to isomorphous substitution of aluminum or silicon atoms of clay mineral particles and balanced by positively cations which present in the water in the void space being attracted to the clay mineral particles. The cations are not held strongly and, if the nature of the water changes can be replaced by other cations, a phenomenon referred to as cation exchange [22]. these positively charged ions (e.g. Ca2+, Mg2+, K+, Na+, H+ and NH4 +) required to balance the charge deficiency on the surface of the clay particles [31]. The type of exchangeable cation of a fine-grained soil has a great influence on its swelling potential [6].
Figure 8 illustrates the results for CEC of both untreated and wastewater treated soil samples. Is it clearly found that, the total CEC was increased with treatment processes with wastewater which rich in organic matter and exchangeable cations (Table 2; Fig. 8).
Organic matter
Organic matter plays an important role in soil engineering and physical properties. The increase of organic content increases the soil plasticity as well as increases the cation exchange capacity owing to large surface area [30, 32]. The initial organic matter content of the studied soil samples varies from 1.84 to 3.58% but after wastewater treatment the organic matter content ranges from 3.11 to 5.21%. The humus organic substances of wastewater have a high specific surface and increases initial the plasticity of the studied soil samples (Table 2).
Swelling characteristics
Swelling pressure
The swelling pressure of the studied undisturbed soil samples was measured directly by: axial free swelling, percentage of swell using the standard one-dimensional odometer apparatus using the following equation:
where PS = swelling pressure (kN/m2), P = load (kg), A = cross sectional area (m2).
The swelling pressure of both untreated and wastewater treated soil samples was found to be (196.1–348.1 kN/m2), and (382.5–549.2 kN/m2) respectively (Table 3; Fig. 9a).
Swell percent
The swelling percentage is defined as the percentage ratio between the increasing in specimen height (ΔH) under a standard stress to the initial height of specimen (H0). The swell percentage is calculated as follows:
where S = swelling percentage, H0 = initial height of the sample (mm), ΔH = increasing in the height of the sample (mm).
The swelling percentages of the studied soil samples are ranging from 21 to 26%, and 37 to 47% for untreated and wastewater treated soil samples respectively (Table 3; Fig. 9b).
Free swelling
The free swell test was carried out as described by Holtz and Gibbs [26]. The free swell test value is given by:
where V2 is in cm3.
A significant higher free swelling value was observed in experiments carried out using wastewater treated soil samples. The free swelling values of the studied soil samples are 64–73%, and 81–92% for untreated and wastewater treated soil samples respectively (Table 3; Fig. 9c).
When the values of swelling pressure of untreated soil samples were compared with the values of treated soil samples, it was found that, a significant higher swelling pressure was observed in experiments carried out using wastewater treated soil samples (Fig. 10). Similarly, respective swell percents were increased (Fig. 11). The swelling of clayey soil when it is subjected to moisture increase is a complicated process found to be influenced by several factors. The swelling percent will be insignificant for initial moisture content slightly higher than the optimum moisture content [19]. As noticed in Figs. 10 and 11, the swelling pressure and swelling percent of the studied clayey soil samples increased when moisture and organic matter content increase.
Correlations between some properties
In the last decay, many researchers were performed to correlate the physical properties with the mechanical properties of soils [1, 4, 5, 27, 38, 41]. This approach was adopted from the earlier researcher in the field of soil mechanics and foundation engineering. These correlations have been considered as a significant part of this work for better understanding of the controlling parameters of plasticity and swelling potentiality of the studied clayey soils. It is clear that, the swelling pressure (kg/cm2) of both initial soil samples (ISS) and wastewater treated soil samples (WTSS) had significant correlations with clay-sized materials percent, organic matter content, liquid limit (%) and CEC (Fig. 12). Furthermore, the CEC has a significant correlation with clay-sized materials percent, organic matter content and liquid limit (%) respectively (Fig. 13).
Conclusions
The current work can be considered as a model for the effect of wastewater on the plasticity and swelling behavior of clayey soil. The above mentioned results allow getting the following conclusions:
-
1.
The flood plain sediments in Sohag Governorate, Upper Egypt can be subdivided into three distinctive units: inorganic clays (CL), well-graded sand (SW) and channel gravels (GW).
-
2.
Mineralogically, the studied soils are composed mainly of montmorillonite (52%), kaolinite (26%), illite–montmorillonite mixed layer (12%) chlorite (8%) and illite (3%).
-
3.
The original plasticity and swelling plasticity potentiality of these clayey soils are strongly correlated with clay-sized materials percent, organic matter content, liquid limit (%) and CEC.
-
4.
The wastewater has great effects on both original plasticity and swelling plasticity potentiality of these clayey soils and changed these soil from medium plasticity and swelling potentiality into highly potentiality.
-
5.
To reduce the geotechnical hazardous effects of municipal wastewater a good sewer net must be done before the beginning construction processes.
References
Abdel-Rahman GE (1982) Correlations between index tests and the properties of Egyptian clay. M.Sc. Thesis, College of engineering, Cairo University
Abu Seif ES (2014) Geotechnical approach to evaluate natural fine aggregates concrete strength, Sohag, Governorate, Upper Egypt. Arab J Geosci. doi:10.1007/s12517-014-1705-3
Abu Seif ES, El-Shater AA (2010) Engineering aspects and associated problems of Nile flood plain sediments in Sohag, Upper Egypt. J Am Sci 6(12):1614–1624
Al-Busoda BSZ (2009) Evaluation and correlations associated with liquid limit and plasticity index of Baghdad cohesive soil. In: The 6th Engineering Conference, Proceedings of the Conference, Civil Engineering, vol 1
Al-Kahdaar RM, Al-Ameri ADI (2010) Correlations between physical and mechanical properties of Al-Ammarah soil in Messan Governorate. J Eng 4(16):5946–5957
Al-Rawas AA (1999) The factors controlling the expansive nature of the soils and rocks of northern Oman. J Eng Geol 53:327–350
Al-Shayea NA (2001) The combined effect of clay and moisture content on the behavior of remolded unsaturated soils. J Eng Geol 62(4):319–342
ASTM (1986) One dimensional swell or settlement potential of cohesive soils. ASTM Standards, 04.08, pp 992–1001
ASTM C136 (2004) Standard test method for sieve analysis of fine and coarse aggregates. ASTM Annual Book of Standards
ASTM D 2974 (2000) Standard test methods for moisture, ash, and organic matter of peat and other organic soils
ASTM D2216 (2005) American Society for Testing and Materials. Test method for laboratory determination of water (moisture) content of Soil and Rock, ASTM Section 4-Construction
ASTM D4318 (2005) Standard test methods for liquid limit, plastic limit, and plasticity index of soils. ASTM Designation D4318-05
ASTM D854 (2006) American Society for Testing and Materials. Standard test method for specific gravity of soils, ASTM Designation D854-06
Basma AA (1991) Estimating uplift of foundations due to expansion: a case history. J Geotech Eng 22:217–231
Basma AA, Al-Homoud AS, Al-Tabari EY (1994) Effects of methods of drying on the engineering behavior of clays. Appl Clay Sci 9(3):151–164
Bergaya F, Theng BKG, Lagaly G (2006) Handbook of clay science. Elsevier, Amsterdam
Buckman HO, Brady NC (1969) The nature and properties of soils. The Macmillan, London
Chapman HD (1965) Cation exchange capacity. In: Black CA, Evans DD, Ensminger LE, White JL, Clark FE, Dinauer RC (eds) Methods of soil analysis, agronomy 9. American Society of Agronomy, Madison, pp 891–901
Chen FH (1988) Foundations on expansive soils, development in geotechnical engineering 54. Elsevier, New York, p 467p
Coduto DP (1999) Geotechnical engineering. Principles and practices. Prentice Hall, Upper Saddle River
CONOCO (1987) The Egyptian general petroleum corporation. Geol Map Egypt 1(500):000
Craig RF (1979) Soil mechanics, 2nd edn. ELBS, London
Dakshanamurthy V, Romana V (1973) A simple method of identifying an expansive soil. Soil Found 13:1
Holtz RD, Kovacs WD (1981) An introduction to geotechnical engineering. Prentice-Hall Inc, Englewood Cliffs
Holtz RD, Krizek RJ (1970) Properties of slightly organic top soils. J Constr Div 96:29–43
Holtz WG, Gibbs HJ (1956) Engineering properties of expansive clays. Trans ASCE 121:641–663
Khamehchiyan M, Iwao Y (1994) Geotechnical properties of Ariake clay in Saga Plain-Japan. J Geotech Eng 29(505):11–18
Mahran TM (1995) Sedimentological development of the upper Pliocene- Pleistocene sediments in the area of El Salamony and El Sawamha Sharq, northeast Sohag, Egypt. Qatar Univ Sci J 15(1):183–194
Mahran TM, El-Shater A, Youssef AM, El-Haddad BA (2013) Facies analysis and tectonic-climatic controls of the development of Pre-Eonile and Eonile sediments of the Egyptian Nile west of Sohag. In: The 7th international conference on the geology of Africa, Assiut, Egypt, (Abstract)
Malkawi AIH, Alawneh AS, Abu-Safaqah OT (1999) Effects of organic matter on the physical and the physicochemical properties of an illitic soil. Appl Clay Sci 14(5–6):257–278
Mitchell JK (1993) Fundamentals of soil behavior, 2nd edn. Wiley, New York
Odell RT, Thornburn TH, Mckenzie LJ (1960) Relationship of Atterberg limits to some other properties of Illinois soils. Proc Soil Sci Soc Am 244:297–300
Omran AA (2008) Integration of remote sensing, geophysics and gis to evaluate groundwater potentiality—a case study in Sohag region, Egypt. In: The 3rd international conference on water resources and arid environments and the 1st Arab Water Forum
Said R (1975) The geological evolution of the River Nile. In: Wendorf F, Marks AF (eds) Problems in prehistory of Northern Africa and the Levant. Southern Methodist University Press, Dallas, pp 1–44
Said R (1981) The geological evaluation of the River Nile. Springer, Heidelberg
Said R (1990) The geology of egypt. In: Balkema SA (ed). Brookfield, Rotterdam
Sánchez-Girón V, Andreu E, Hernanz JL (2001) Stress relaxation of five different soil samples when uniaxially compacted at different water contents. Soil Tillage Res 62(3–4):85–99
USDA (2004) Correlations between soil plasticity and strength parameters. Advanced Engineering Geology and Geotechnics, GE441, USDA-NRCS, US. USDA: National Soil Survey Characterization Data
Williams AAB (1980) Severe heaving of a block of flats near Kimberley. In: Proceedings 7th regional conference for Africa on soil mechanics and foundation engineering, Accra, vol. 1, pp 301–309
Yilmaz I, Civelekoglu B (2009) Gypsum: an additive for stabilization of swelling clay soils. J Appl Clay Sci 44(1–2):166–172
Yilmaz I (2000) Evaluation of shear strength of of clayey soils by using their liquidity index. Bull Eng Geol Environ 59:227–229
Yilmaz I (2006) Indirect estimation of the swelling percent and a new classification of soils depending on liquid limit and cation exchange capacity. J Eng Geol 85:295–301
Yilmaz I (2008) A case study for mapping of spatial distribution of free surface heave in alluvial soils (Yalova, Turkey) by using GIS software. J Comput Geosci 34(8):993–1004
Yilmaz I (2009) Swell potential and shear strength estimation of clays. J Appl Clay Sci 46(4):376–384
Yilmaz I, Kaynar O (2011) Multiple regression, ANN (RBF, MLP) and ANFIS models for prediction of swell potential of clayey soils. Expert Syst Appl 38(5):5958–5966
Acknowledgements
The author therefore, acknowledge and thank the editor-in-Chief of International Journal of Geo-Engineering journal and the anonymous reviewers for insightful comments and criticism that improved the original manuscript.
Competing interests
The author declares that he has no competing interests.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Seif, ES.S.A. Geotechnical hazardous effects of municipal wastewater on plasticity and swelling potentiality of clayey soils in Upper Egypt. Geo-Engineering 8, 1 (2017). https://doi.org/10.1186/s40703-016-0038-3
Received:
Accepted:
Published:
DOI: https://doi.org/10.1186/s40703-016-0038-3