Abstract
Physicochemical analysis was performed on 32 groundwater samples around the municipal solid waste dump yard, Ariyamangalam, Tiruchirappalli. The dump yard is 12 km from the city dumping that is around 500 tons per day. The parameters such as TDS, turbidity, alkalinity, pH, Mg, NH3, \( {\text{NO}}_{3}^{ - } \), \( {\text{NO}}_{2}^{ - } \), total hardness, Na, K, F, Cl−, SO42−, BOD and COD were tested using standard testing procedures according to IS 3025. The obtained values were compared with BIS 10500. The WQI has been calculated using AW method, and statistical analysis such as variance, standard deviation, correlation, histogram with its distribution and principal component analysis has been performed using SPSS 16.0. The spatial variation of the parameters has been interpolated by using geographical information system as a platform. Using GIS interpolation, the values at the location where the data are not known can be inferred with the known set of values. ArcGIS 9.3 software has been used as an effective tool for the spatial variation mappings. The results suggested the need for adjusting factors managing the solid waste that leads to reduce the leachate contamination of groundwater with repeated monitoring of groundwater quality and leachate percolation.
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Introduction
The solid waste from the panchayats in villages and municipalities in towns is due to trash/garbage that consists of many items thrown away. This comes from residential places, schools, colleges, hospitals, businesses, etc., (Mudgal et al. 2011). In some places, municipal solid waste is openly dumped without any treatment, segregation or cover (Vasanthi et al. 2008; Akoteyon et al. 2011). In such a site, the product produced due to the biochemical changes in the organic substances and due to moisture penetration is called leachate (Aderemi et al. 2011). When moisture penetrates the landfill, it converts the contaminants into liquid phase, and when the moisture is high, it initiates a liquid flow (Jhamnani and Singh 2009). Leachate is an organic/inorganic compound from landfills. Percolation of leachate contaminates the groundwater. The type of contamination from solid waste disposal becomes a big issue to the environment (Abu-Rukah and Al-Kofahi 2001).
‘Leachate is produced when moisture enters the refuse in a landfill, extracts contaminants into the liquid phase and produces moisture content sufficiently high to initiate liquid flow (Lo 1996). The presence of bore well at the landfill sites to draw groundwater threatens to contaminate the groundwater’. The Ariyamangalam garbage ground near Trichy is an open dumpsite for leachate collection (Nagarajan et al. 2012). Open dumps are unhygienic and generally smelly with many types of human waste, animal waste, medical, pharmaceutical waste, etc. (Akinbile and Yusoff 2011). In addition heavy metals in chemicals lead to bioaccumulation and bio-magnifications. The aim of this present investigation is (1) to study the chosen solid waste dump yard site (Ariyamangalam, Trichy, Tamil Nadu), (2) to analyse the groundwater quality around the dumpsite for contamination caused due to leachate (Aderemi et al. 2007, 2011, El-Salam and Abu-Zuid 2014) and (3) to determine the possible impact of groundwater contamination on the environment. Water quality index, which is an indicator of water quality, has been calculated using arithmetic weighing method and collated between parameters (Terrado et al. 2010; Yisa and Jimoh 2010). The probability distributions (PD) and principal component analysis (PCA) have been computed through Statistical Package for the Social Sciences (SPSS) software. From the analysis the average rainfall is + 28%, evapotranspiration is + 28%, and average precipitation is 20%.
Study area
Geography of the study area
Trichy is a metropolitan city and has a population ~ 28 lakhs, 602 inhabitants per km2. The temperature is 18.90 (min) and 37.70 (max) (Banar et al. 2006; Esakku et al. 2007). The location of the dump yard is 10,048′0″N and 78043′0″E and has an elevation of 75.87 m above MSL. The study was conducted outside the city about 12 km towards Tanjore (Trichy–-Tanjore National Highway (NH 67)). The study area has alluvial type of soil (Data source: Public Works Department, Tamil Nadu, India).
Waste generation and characterization
The municipal solid waste in Trichy city is shown in Fig. 1 (yearly). The generation of waste is due to population, economic development, packaged foods, packaged water and other items and an average of 470 tons of waste per day on dumpsite (Shenbagaraj 2013). The total surface area of the dump yard is 193,035.1 Sq. met. and has been operated since 1967 (Mor et al. 2006). An area of 169,968 Sq. met. is filled with garbage with height of 4.877 m. There are some industries’ waste, boiler plants waste, vegetable waste (Gandhi market), etc., (Venkateswararao and Raju 2013). The minimum temperature is 31.1 °C and the maximum temperature is 36.1 °C.
Figure 1 shows the types of waste and their percentage, and the sampling of 32 locations is shown in Fig. 2a graphically.
Materials and methods
Methodology
The work is started by collecting the literature pertaining to the chosen area of work. Then, the sampling procedures are studied (IS 3025: 2011, 1984). Sampling shall be carried out and tested for many physicochemical parameters and heavy metals (Kanmani and Gandhimathi 2013a, b). With the obtained results, special variation maps shall be generated using ArcGIS and a conclusion can be arrived with statistical analysis.
Sampling
Random sampling of groundwater has been done from 32 locations within an area of 10 km2 and was labelled as S1 to S32 which were chosen on random basis of sources (Fig. 2b–f). The locations were noted through the hand GPS-GARMIN Etrex 30. The sampling was done in February 2016 after the rainy season. Eighteen hot spot samples were collected and tested to know the level of leachate contamination and control of groundwater to observe decreasing trend of contamination as the distance from the dump yard to the source.
Instrumental analysis
The analysis of the samples of pH, electrical conductivity (EC), turbidity and dissolved oxygen (DO) was performed in laboratory through portable meters (Systronics Limited, India). Total dissolved solids’ (TDS) values were obtained by recalculation of the EC measurements. Further the alkalinity through acid base titrations, hardness through hardness titration (EDTA) procedure which are in BOGUE, and the ions are determined through spectrophotometer (SpectroDirect, Tintometer Ltd., Germany).
Water quality index (WQI)
The water quality index values of all samples are computed through the following formula:
where Mi = laboratory-estimated values of the ith parameter, Ii = ideal value of the ith parameter, and Si = standard value of the ith parameter.
Table 1 shows the quantity data of Ariyamangalam dump yard which gives information about the total area, area filled, maximum height of garbage, average height of garbage and current rate of dumping WQI of quality of water.
The same Table 1 shows the classification of quality based on WQI values. From the calculated WQI values compared with their specific locations reported in (Irena et al. 2016).
Spatial variation mappings
Spatial mapping has been done using the 3D analysis tool for raster interpolation modelling in IWD options in ArcGIS 9.3 software.
Statistical analysis
Basic statistics for the median, mode, variance and standard deviation has been found. The correlation matrix, histograms with their probability distributions, principal component analysis (PCA) and the scree plots have been obtained using SPSS (Statistical Package for the Social Sciences).
Results and discussion
Water quality index (WQI)
From the WQI of 32 groundwater samples, it was found that 34.37% has poor quality, 37.5%—very poor in quality, 12.5%—good in quality and better for human usage, 6.25%—excellent quality and best for human usage in particular drinking purpose, and 9.37%—unfit for drinking and danger for human usage not only for drinking but also for washing purposes (Fig. 1). Table 2 shows the values of water quality index calculated using arithmetic weighing method.
The analysis suggested that more than 50% of the samples have poor quality including 12.5%—very poor and 9.37%—unfit for drinking.
Spatial variation of the parameters
From the obtained values of the laboratory analysis with respect to the location of sampling points, the spatial variation maps of the parameters have been plotted. This gives an overall idea about the contamination that has been spatially distributed in the chosen area. The process of spatial distribution is the points with the known values to estimate the values at the other points. From spatial interpolation, the values at the location where the data are not known can be inferred. The spatial interpolation and the range of distinguishing for the spatial mapping have been specifically set for each parameter. The minimum and maximum values of EC have been 694 and 4920, respectively (mic mho sec−1), and all the samples have exceeded the acceptable limits of BIS10500 (Manoj and Pravin 2015). The minimum and maximum values of TDS have been 584 and 5644, respectively (mg/l), and all the samples have been found to be greater than the acceptable limits of BIS10500 (Fig. 3). The minimum and maximum values of fluoride have been 0.1 and 1.0, respectively (mg/l), and all the samples have been found within the acceptable level of BIS10500. The minimum and maximum values of calcium have been 52 and 873, respectively (mg/l), and 93% of the samples have gone beyond the acceptable limits of BIS10500. The minimum and maximum values of chloride have been 85 and 3160, respectively (mg/l), and 31% of the samples have exceeded the acceptable limits of BIS10500. The minimum and maximum values of nitrate have been 10 and 58, respectively (mg/l), and 12.5% of the samples have exceeded the acceptable limits of BIS10500 (Fig. 4). The minimum and maximum values of total alkalinity have been 44 and 660, respectively (mg/l), and 28% of the samples have gone beyond the tolerance limits of BIS10500 (Fig. 5). The minimum and maximum values of sulphate have been 28 and 210, respectively (mg/l), and 3% of the samples have more than the acceptable limits of BIS10500. The minimum and maximum values of total hardness have been 190 and 3590, respectively (mg/l), and 96% of the samples have more than the acceptable limits of BIS10500 (Suratman et al. 2015; Aweng et al. 2011; Hussain et al. 2013). All the spatial variation values are depicted in Figs. 3, 4, 5, 6, 7, 8, 9 and 10.
Statistical analysis
The concepts of data reduction and descriptive statistics have been used in SPSS to produce the required statistical results. Factor analysis has been performed to find out the possible set of sources from the component and rotated component matrix. The 3D component plot has been obtained which can give a better idea of the statistical output by means of the statistical procedure as principal component analysis (PCA).
These values are presented in Table 3, which contains the mean, median, mode, variation and standard deviation (SD) of the data of the various targeted parameters.
The 55% of the samples were almost of poor quality, out of which 12% were very poor and 9% were found unsuitable for drinking.
From the rotated component matrix, it is inferred that (component 1) hardness, calcium, magnesium, chloride, sodium, EC and potassium are from the same source of leachate from the dump yard.
Fluoride, nitrite and nitrate (component 2) are from a similar source which can be fertilizers. BOD and COD (component 3) are from a common source, an improper disposal of industrial effluent (Table 4).
Correlation
The correlation for all the tested values which gives the statistical relationship between the parameters has been found and represented in matrix form. The correlation matrix has been obtained for all the parameters chosen to be tested. From this, the strongly correlated parameters can be found on the basis of the correlation value. A value above 0.6 is taken as strong correlation. Table 6 shows the correlation matrix of obtained data set.
Table 5 lists the strongly correlated parameters, which shows that the relation between each parameter has been strong (value above 0.6) from which it is evident that these contaminations in the groundwater are from the same leachate from the solid waste dump yard (Aderemi et al. 2007, 2011). From the values obtained from the correlation matrix, the strongly correlated parameters have been found.
Histograms and probability distributions
Graphical representation (histogram) of theoretical and experimental distribution curves produces a particular result. Normal curve is a continuous function which is characterized by mean and standard deviation. Poisson curve is a discrete function, and exponential curve is again a continuous function (Kobya et al. 2012). The histograms of the EC, pH, TDS and nitrite are shown in Fig. 11. The histograms of alkalinity, nitrate, hardness and chloride are shown in Fig. 12. The histograms of potassium, calcium, sodium and magnesium are shown in Fig. 13. The histograms of BOD, COD, sulphate, fluoride are shown in Fig. 14. They are distributed as Poisson, normal and exponential distributions (Manoj et al. 2016; Krishnaraj et al. 2015). It has been inferred that the trend of distribution will retain irrespective of the number of samples. Any number of samples in the same belt of the study area will give the similar type of probability distribution.
The variable X can take on the values of the parameters tested. In this histogram (Fig. 11), X is a random variable which is the outcome of statistical experiment. Descriptive statistics is a method for summarizing the data. For these bell-shaped distributions, the mean values are 68% for one standard deviation, 95% for two standard deviations and 99.7% for three standard deviations were found.
A Poisson distribution is the statistical tool gives the status of experiment has the properties are successes or failures. From Fig. 12, the number of successes (μ) that occurs in a particular region is known. And the probability, the possibility or existence of success has the same trend and proportional to the size of the specified region, but is very small and considered as negligible.
Figure 13 shows the mean and standard deviation occurred as normally distributed bell-shaped curve. It shows the symmetrical density curve which is determined through standard deviation. The normal distribution is zero, because the ‘x’ lies away from the mean. And so it is not suitable method for distribution analysis, and robust statistical inference methods were adopted.
Obtain the unknown future data through known data, the predications of this method are called plug-in distribution model, and the value estimated through rate parameter ‘λ’ is shown in Fig. 14.
Principal component analysis (PCA): it is the process used to convert a set of correlated variables into uncorrelated variables, and they are given in Table 6
Table 6 shows the principal and rotated component matrix. The mathematical approach used in PCA is called eigenanalysis through eigenvalues and eigenvectors of rows or column of the component matrix.
From Table 6, the rotated component matrix which is the component matrix converged to its fifth iteration. A component value close to 0.8 is taken for interpretation. Thus, with regard to that, hardness, calcium, magnesium, chloride, EC, sodium and potassium have values above 0.8 in the first component. This infers that the source of these contaminations is same which can possibly from leachate of the solid waste dump yard (Manoj and Pravin 2015). Similarly, nitrite and nitrate have component value above 0.9 in the second component which shows that it has the same source for which fertilizer can be a reason. In the third component, BOD and COD have considerable values which can be from an improper industrial effluent disposal (Manoj et al. 2016).
Figure 15 shows the component plot which exhibits all the three components and its corresponding values, which gives the clear idea about the sources of contamination. The plot is a 3D plot of the rotated component matrix which shows the stand of the component value of each parameter in the system.
Conclusion
From the work done, it is confirmed that the groundwater quality is affected by the leachate from the studied dump yard. The generation of contamination is due to the increase in pollution which is the key parameter being identified. Construction of engineered landfill and geosynthetic clay liners (GCL) can decrease the rate of seepage of leachate into the soil to reach the water table. There are a few contaminations apart from the leachate source. From the principal component analysis, it is inferred that two other sources of contaminations are also present. It shows that nitrite and nitrate are obtained from the same source which can be fertilizers used around the location of the study area. BOD and COD are from a similar source which can be from an improper industrial effluent disposal.
References
Abu-Rukah Y, Al-Kofahi O (2001) The assessment of the effect of landfill leachate on ground-water quality—a case study. El-Akader landfill site—north Jordan. J Arid Environ 49(3):615–630
Aderemi AO, Oriaku AV, Adewumi GA, Otitoloju AA (2011) Assessment of groundwater contamination by leachate near a municipal solid waste landfill. Afr J Environ Sci Technol 5(11):933–940
Adeyemi O, Oloyede OB, Oladiji AT (2007) Physicochemical and microbial characteristics of leachate-contaminated groundwater. Asian J Biochem 2(5):343–348
Akinbile CO, Yusoff MS (2011) Environmental impact of leachate pollution on groundwater supplies in Akure, Nigeria. Int J Environ Sci Dev 2(1):81–89
Akoteyon IS, Mbata UA, Olalude GA (2011) Investigation of heavy metal contamination in groundwater around landfill site in a typical sub-urban settlement in Alimosho Lagos-Nigeria. J Appl Sci Environ Sanit 6(2):155–163
Aweng ER, Ismid MS, Maketab M (2011) The effects of land use on physicochemical water quality at three rivers in Sungai Endau watershed, Kluang, Johor, Malaysia. Aust J Basic Appl Sci 5(7):923
Banar M, Ozkan A, Kurkcuoglu M (2006) Characterization of the leachate in an urban landfill by physicochemical analysis and solid phase micro extraction-GC/MS Environ. Monit Assess 121(1–3):439–459
El-Salam MMA, Abu-Zuid GI (2014) Impact of landfill leachate on the groundwater quality: a case study in Egypt. J Adv Res 6:579–586
Esakku S, Obuli Kartikeyan P, Joseph K, Nagendran R (2007) Seasonal variation in leachate characterization from municipal solid waste dumpsite in India Srilanka. In: Proceedings of international conference on sustainable solid waste management, Chennai, India, pp 341–347
Hossain MA, Sujaul IM, Nasly MA (2013) Water quality index: an indicator of surface water pollution in eastern part of Peninsular Malaysia. Res J Recent Sci 2(10):10
IS 10500, 1991-2011 (2011) Water quality standard, Indian Standard for drinking
IS 3025-8 (1984) Methods of sampling and test (physical and chemical) for water and wastewater, Part 8: Taste rating [CHD 32: Environmental Protection and Waste Management]
Jhamnani B, Singh SK (2009) Groundwater contamination due to Bhalaswa landfill site in New Delhi. Int J Environ Sci Eng 1(3):121–125
Kanmani S, Gandhimathi R (2013a) Investigation of physicochemical characteristics and heavy metal distribution profile in groundwater system around the open dump site. Appl Water Sci 3(2):387–399
Kanmani S, Gandhimathi R (2013b) Assessment of heavy metal contamination in soil due to leachate migration from an open dumping site. Appl Water Sci 3(1):193–205
Krishnaraj S, Kumar S, Elango KP (2015) Spatial analysis of groundwater quality using geographic information system–a case study. Magnesium (as Mg), 30, 100
Lo IMC (1996) Characteristics and treatment of leachates from domestic landfills. Environ Int 22(4):433–442
Manoj W, Pravin N (2015) Treatment of distillery spent wash by using coagulation and Electro–coagulation (EC). Am J Environ Prot 3(5):159–163
Manoj PW, Nana MM, Nemade PD (2016) Electro-coagulation (EC) process to treat basic dye. Int J Dev Res 06(05):7858–7862
Mehmet K, Demirbas E (2012) Effect of operational parameters on the removal of phenol from aqueous solutions by electro coagulation using Fe and Al electrodes. Desalin Water Treat 46:366–374
Mor S, Ravindra K, Dahiya RP, Chandra A (2006) Leachate Characterization and assessment of groundwater pollution near municipal solid waste landfill site. Environ Monit Assess 4:325–334
Mudgal S, Lyons L, Bain J (2011) Plastic waste in the environment–revised final report for European Commission DG environment. BioIntelligence Service. http://www.ec.europa.eu/environment/waste/studies/pdf/plastics.pdf
Nagarajan R, Thirumalaisamy S, Lakshumanan E (2012) Impact of leachate on groundwater pollution due to non-engineered municipal solid waste landfill sites of erode city, Tamil Nadu, India. Iran J Environ Health Sci Eng 9(1):1–12
Naubi I, Zardari NH, Shirazi SM, Ibrahim NFB, Baloo L (2016) Effectiveness of water quality index for monitoring malaysian river water quality. Pol J Environ Stud 25(1):231–239
Satyavathi VVC, Venkateswararao B, Raju PM (2013) Physicochemical and microbial analysis of ground water near municipal dump site for quality evaluation. Int J Bioassays 2(08):1139–1144
Shenbagarani S (2013) Analysis of groundwater quality near the solid waste dumping site. J Environ Sci Toxicol Food Technol 4(2):2319–2399
Suratman S, Sailan MI, Hee YY, Bedurus EA, Latif MT (2015) A preliminary study of water quality index in Terengganu River basin. Malaysia, Sains Malaysiana 44(1):67
Terrado M, Borrell E, Campos S, Barcelo D, Tauler R (2010) Surface-water-quality indices for the analysis of data generated by automated sampling networks. Trends Anal Chem 29(1):40
Vasanthi P, Kaliappan S, Srinivasaraghavan R (2008) Impact of poor solid waste management on ground water. Environ Monit Assess 143:227–238
Yisa J, Jimoh T (2010) Analytical studies on water quality index of River Landzu. Am J Appl Sci 7(4):453
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The authors gratefully acknowledge the Management and Authorities, SRM University, Tamil Nadu, India, for providing the necessary facility to complete this work in a successive manner.
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Justus Reymond, D., Sudarsan, J.S., Annadurai, R. et al. Groundwater quality around municipal solid waste dump in Tiruchirappalli (South India). Int. J. Environ. Sci. Technol. 16, 7375–7392 (2019). https://doi.org/10.1007/s13762-018-2063-6
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DOI: https://doi.org/10.1007/s13762-018-2063-6