Assessment of Physiochemical Properties and Heavy Metals Concentration of Municipal Solid Compost (MSWC): A Case Study in Sokoto Metropolis, Nigeria ()
1. Introduction
Municipal solid waste is a by-product of human activities, that is unwanted and abandoned (Ibikunle et al., 2018) [1] . These wastes are collected by waste collectors and vary by location (Lin et al., 2015 [2] ; Huseyin et al., 2016 [3] ; Read, 1999 [4] ). Combustible and non-combustible materials make up the waste generated and their indiscriminate disposal leads to environmental degradation, pollution and global warming (Zhou et al., 2014 [5] ; Ibikunle et al., 2018 [1] ). According to the latest estimates from the World Bank (2022) [6] , 1.3 billion tons of solid waste is generated globally every year, or 1.2 kg per person per day. The situation is expected to worsen as 2.2 billion tons of waste is expected to increase by 2025 (Izionworu and Akpa, 2018) [7] . However, out of 32 million tons of solid waste Nigeria produced each year only 20-30% is recycled (Bakare, 2022) [8] and the remaining end in open dumpsite. According to Babatunde et al, (2013) [9] , about 25 million tons of municipal solid wastes are generated annually, at 0.44 to 0.66 kg per day. This harms the environment but if managed will make adequate materials available for energy production, composting, and recycling, respectively (Bhat et al., 2018) [10] . However, rapid urbanization in Nigeria has made municipal solid waste management a serious environmental issue (Chen et al., 2012 [11] ; Banna et al., 2014 [12] ; Ziraba et al., 2016 [13] ). In sub-Saharan African countries like Nigeria, waste management receives less than 10% of urban council budgets (Oosterveer et al., 2010) [14] . This leads to uncollected MSW and poor management of landfills (Rogger et al., 2011 [15] ; Komakech et al., 2014 [16] ; Komakech et al., 2016 [17] ). Most of these wastes (more than 90%) are used for unscientific land filling or uncontrolled dumping on the outskirts of towns and cities (Sharholy et al., 2008 [18] ; Narayana, 2009 [19] ). However, excessive waste in soil may increase the heavy metal content in groundwater and soil. Soil, crops and human health can all be negatively affected by heavy metals (Nyle and Ray 1999 [20] ; Smith et al., 1996 [21] ).
Time is running out; our world will soon be covered in waste if waste is not managed properly (Nadeem, Farhan, and Ilyas, 2016) [22] . Composting of MSW appears to be an excellent choice for disposing of MSW. It’s an inexpensive technology to keep organic waste out of landfills and produce quality products for agriculture (Nsimbe et al., 2018) [23] . Municipal waste increased nitrogen, pH, cation exchange capacity, % alkali saturation and organic matter, it was claimed. Given that organic waste can enhance plant development by providing nutrients, continued land use of these wastes may be encouraged (Anikwe and Nwobodo, 2001 [24] ; Nyles and Ray 1999 [20] ). MSWC can be used in agriculture as a soil conditioner and fertilizer, which is more cost-effective for small farmers to use than inorganic fertilizers (Mandal et al., 2014 [25] ; Jodar et al., 2017 [26] ). In addition, there are concerns about the toxicity of solid waste when it is separated at source to reduce composting (Hargreaves et al., 2008) [27] .
Lack of pre-separation during composting can result in poor quality compost. Crop growth is negatively affected by nutrient abundance and deficiency, which also adversely affects the soil and creates bioaccumulation (Emamverdian et al., 2015) [28] . Toxic metals migrate into crops as a result of application of municipal solid waste compost to agricultural fields in excess of heavy metals. Large amounts of these heavy metals can cause nausea, vomiting, diarrhea, and pneumonia (Jaishankar et al., 2014) [29] . These heavy metals can bind to biological components. Depending on the characteristics of the soil and compost, it is crucial to evaluate the characteristics and heavy metal content of the compost before applying it as a soil supplement in agricultural areas.
This study, therefore aimed at assessing physiochemical parameters and concentration of some selected heavy metals in solid municipal waste compost from different dumpsites within Sokoto metropolis.
1.1. Study Area
Sokoto is a city located in the extreme northwest of Nigeria, near the confluence of the Sokoto River and the Rima River (Figure 1). It occupies 25,973 square kilometres with a population of 563,861. Geographically situated between latitude 130˚.05 and 13˚.0830 north and longitude 05˚15 and 5.250˚ east with an average elevation of 272 m above sea level. The ten (10) sampling dumpsites selected were all within Sokoto Metropolis. These were Bado (BDO), Dallatu (DLT), Gawon-Nama (GNM), Kalanbaina (KBN), Kwannawa (KMW), Gidan dare (GDR), Marina (MRN), Tudun-wada (TWD) and Runbukawa (RKW).
1.2. Sample Collection and Treatment
Compost samples were collected in triplicate from various windrow depths and portions at each location (compost plants) to create composite samples. To guarantee complete population representation, samples of the compost manure
Figure 1. Location of the dumpsites area studied in Sokoto, Nigeria.
were taken from the upper 2 - 3 m, middle 1 - 2 m, and lower 0 - 1 m levels. Each sample weighed about 200 g. Each composite sample was thoroughly mixed, separated, and 20 g of it was sub-sampled (reduced). This portion was then air-dried at room temperature to stop biological activity, ground in a mechanical motor and pestle, sieved through an agriculture 2 mm screen to ensure a homogeneous mixture, placed in air-tight, labelled, clean polyethylene bags, transported to the lab in an icebox, and stored for additional analysis.
2. Materials and Methods
2.1. Determination of Total P and Total N
Total P and Total N were determined by Kjeldhal process using a standard AOAC Method 978.02, as reported by Okalebo et al, (2002) [30] .
2.2. Determination of Ca, Na, Mg and K
The samples were digested using wet digester method. After digestion, the produced solutions were used to analyzed K and Na using flame photometer by inserting appropriate filter. Ca and Mg content of the samples were determined using EDTA titration method (Horwitz et al., 2005) [31] and their amount calculated using Equations (1) & (2)
(1)
(2)
where: T is titre of the sample, N normality of EDTA, wt weight of sample and V of the leachate collected.
Amount of Mg2+ was determined by subtracting amount of Ca2+ from Ca2+Mg2+ obtained in Equation (1)
2.3. Proximate Analysis
The pH and EC of the samples were measured in aqueous suspension using a pH meter and conductivity meter in 1:10 % using AOAC standard method (AOAC 973.04) [32]
The moisture contents of the samples were determined using standard test method for residual moisture analysis (ASTM 3173) [33] .
(3)
where W0 = weight of empty crucible, W2 = weight of crucible and the sample before oven drying, and W1 = weight of crucible and the sample after drying.
Ash content of the samples was determined using Equation (4), following a standard ASTM method (ASTMD, 3174) [34]
(4)
where W0 = weight of empty crucible, W2 = weight of crucible and the sample before combustion and W1 = weight crucible and the sample after combustion.
Organic Volatile Matter was determined using standard method (ASTMD, 3175) [35] and calculated using Equation (5)
(5)
where W1 = weight of the sample and W2 = weight of the Sample after incineration
Fixed carbon was determined by difference using Equation (6).
Fixed Carbon (%) = 100 ? (% moisture content + %Ash + % volatile matter) (6)
2.4. Heavy Metal Analysis
Heavy metals were determined by atomic absorption spectroscopy (AAS) using the standard methods adapted by USEPA 7000a (Schrenk et al., 2012) [36] . Extractor and AAS controls were turned on and the thin tube, atomizer parts was cleaned with purge wire, while the burner opening with an alignment card. The ASS worksheet was opened. The lamp was turned on, to allow the light beam from the cathode strike the target area of the card. The fine was placed in 10 ml graduated chamber filled with deionized water. An analytical blank was prepared together with series of calibration solutions of known amounts of analyte. Blanks and standards were nebulized in sequence and their responses measured. A calibration chart is drawn for each solution, after which the sample solution is nebulized and measured. The metal concentration was determined based on the absorbance obtained for the unknown sample from the calibration.
3. Results and Discussion
One of the parameters used to check the quality of compost is its heavy metal concentration. Dyes, batteries, electronics, cosmetics and pharmaceutical residues are the main sources of heavy metals in compost (Amouei et al., 2009) [37] . Due to the harmful effects of heavy metals on humans and the environment, some standards have been established for the concentration of these metals in compost. In this study, the average concentrations of heavy metals detected in the compost from different landfills were 275.47 ± 89.86, 1.82 ± 1.04, 82.44 ± 28.28, 263.46 ± 91.46, 45.23 ± 11.72, 1.53 ± 0.095, 71.71 ± 21.46 and 0.29 ± 0.39 mg/kg for Zn, Cd, Fe, Cu, Ni, As, Pb, Mn and Cr respectively. The mean concentrations of the heavy metals were all within the allowed limits of the USA and the UNBS/ICS Standard (Figure 2). High concentrations of heavy metals limit the use of compost on farmland. Environmental impact of heavy metal-contaminated compost varies with soil type, plant species, and compost quality (Zhao et al. 2011) [38] .
All the compost samples show high concentration of Zn compared to others heavy metals detected with Cd concentration been the least. This is in line with the findings of Ibrahim et al, (2020) [39] , for the heavy metals analysed in municipal solid waste from Potiskum (Yobe State, Nigeria). The higher concentration
Figure 2. Heavy metals concentration of the compost compared with the standard.
of Zn in the compost may be due to the stability of ZnO, as ZnO in soil has a higher stability coefficient (Ma and Rao, 1997) [40] . The low concentration of Cd may be attributed to the weak adsorption properties of Cd (Mido and Satake, 2003) [41] .
3.1. Correlation between Heavy Metal Concentrations in the Compost
Pearson’s correlation analysis was carried out to analyze correlations between heavy metal concentrations in the compost from different sites. Result of the analysis is shown in (Table 1). It represents the correlation between different dumps in terms of heavy metal concentrations. The analysis revealed a strong positive correlation of heavy metal between the sites. This may be due to the correlation in composition of the solid waste from the different dumping sites.
3.2. Statistical Analysis
A one-way analysis of variance (Table 2) was performed to determine significant differences in terms of heavy metal concentrations among the different studied sites. The analysis was based on probability level (α) of 0.05. The ANOVA results revealed that there were no significant differences in concentrations of heavy metals from the dump sites (p-value > 0.05). A low value of calculated F (0.2531) also predicts a non-significant difference when compared to the critical F value of 1.999.
The moisture content of the sample was in the range of 1.13 - 2.23 with an average value of 2.00% ± 0.52%. High moisture content reduces air space, so the compost can become clumpy. Dusty compost is often generated by compost ventilation, causing ambient air pollution in the surrounding area (Mandal et al.,
Table 1. Pearson’s correlation coefficient for heavy metal concentrations in the compost.
Table 2. Result of one way analysis of variance (ANOVA).
2014) [25] . The pH of the compost varied from 6.78 to 7.47 with an average value of 7.06 ± 0.22, which indicates that it was almost acidic to slightly alkaline, and was found to be within the standard recommended range of 6 to 8 (WHO). A high pH accelerates the release of ammonia from the compost into the ambient air. A gradual increase in ammonia emissions to ambient air corresponds to an increase in compost temperature (35˚C - 60˚C) and alkaline pH value (Omrani et al. 2004) [42] . Disease-causing pathogens may be present in compost, during waste sorting and transportation; pathogenic bacteria can cause illness in those who handle them. The values of pH obtained indicated that the composts were not adulterated with pathogenic bacteria. This may be due to increased temperatures, which destroy pathogens (Day and Shaw 2001) [43] .
The nutrients in the compost were analyzed to determine its suitability for agricultural land. Nutrients are needed in compost piles because microbes need them to grow, besides their importance in terms of fertilizer value (Sadeghi et al., 2015) [44] . Among the nutrients, Carbon, Nitrogen, Phosphorus, Potassium, Calcium, Iron, and Manganese are the most important (Abbasi et al., 2010) [45] . The average values of Nitrogen, Phosphorus, and Potassium in the compost are 2.29 ± 0.86, 1.92 ± 0.3, and 55.27 ± 13.68 mg/kg, respectively. WHO standards for nitrogen, phosphorus and potassium in compost are 0.4 - 3.5, 0.3 - 3.8 and 0.5 - 1.8, respectively (Table 3). The values recorded in this study meet WHO standards with exception of potassium, which was found to be higher than the
Table 3. Physiochemical properties of the compost.
specified limit. Electrical conductivity indicates concentration of dissolved salts in the compost. Composts with high concentrations of EC can cause problems such as soil salinity and biotoxicity (Malakootian et al., 2014) [46] . The average electric conductivity of the compost was found to be 3.31 ± 1.18. High electrical conductivity in compost inhibits seed germination and plant growth (Rahman et al., 2020) [47] . The C:N ratio of the composts varied from 2.28 to 9.51 with an average value of 7.02 ± 1.92. Stable mature composts that do not contain lignocellulosic material have CN ratios below 17 (Silva et al., 2007) [48] . Some literature suggests an ideal value of 12, while others suggest a CN ratio of 20-40 as most suitable for use as a fertilizer (Rawat et al., 2013) [49] . Composts with CN ratio values above or below the recommended values may inhibit seed germination, reduce plant growth, and cause phytotoxicity due to insufficient biodegradable organic matter, thereby damaging crops (Kabasiita et al., 2022) [50] . Organic matters affect the quality of compost. The results in this study showed that organic matter in the compost ranges from 0.94 - 14.78 having average value of 14.39% ± 1.94%. Organic matter indicates the presence of heavy metals in compost as they are known to form complexes with organic matter (Jimoh and Sabo, 2013) [51] . A low OC indicates mature and stable composts (Kabasiita et al., 2022) [50] ; thus, these composts will be stable and usable for on-farm applications due to the low organic matter content of the composts.
4. Conclusion
The application of municipal solid waste compost for agricultural purposes is rapidly growing. The composts are made of different sources of materials. To ensure the quality and safety of compost, it is necessary to analyze and monitor its physical and chemical characteristics. In this study, the physiochemical properties and heavy metal analysis of municipal solid waste compost from different dumpsites within Sokoto City were investigated. Results indicated a good quality of the studied compost with only a limited number of parameters outside the specified limits of USA, UNBS/ICS, and WHO standards.
Acknowledgements
The authors acknowledged and expressed their gratitude and appreciation to the Tertiary Education Trust Fund (TETFund) for financial support to carry out this research under Institutional Based Research (IBR) with a number (Bach 7: 2015-2021 Merged Intervention S/NO7).