Neem (Azadirachta indica) Leaves for Removal of Organic Pollutants

Abstract

Neem (Azadirachta indica) leaves was employed in a batch adsorption technique for the detoxification of congo red (CR) and methyl orange (MO) dyes from a single component model wastewater. The adsorption efficiency of the leave was judged based on changes of parameters like agitation time, adsorbent dosage, adsorbent particle size, and adsorbate initial concentration and pH. Adsorbate concentration during the adsorption process was monitored using T60-U UV-Visible spectrometer from TG Instruments. While FTIR and SEM were employed to study the surface functional group and morphological changes of the adsorbent before and after the adsorption process. Percent adsorption increased with increase in agitation time (5 - 240 minutes), adsorbent dosage (0.1 - 0.5 g), initial concentration (100 - 300mg/L), and with decrease in particle size (≥75 μm to ≤300 μm) of adsorbent. The adsorption processes were found to be pH-dependent, increasing or decreasing in acidic (pH 2 - 6) or alkaline (pH 8 - 12) range over the studied pH (2 - 12) range. The correlation coefficient (R2 – values) ranging from 0.9359 - 0.9998 shows good agreement of the experimental data for all the tested isotherms. The monolayer maximum adsorption capacity for Langmuir’s qm (18.62 - 24.75mg/g) and Dubinin-Radushkevich, qD (20.72 - 26.06mg/g) are comparable. Both Langmuir’s separation factor (RL) and Freundlich constant (nF) suggests unfavourable adsorption of the dyes onto the adsorbent. The mean free energy of adsorption, ?? (79.06 - 316.23 J/mol) calculated from Dubinin-Radushkevich equation suggest a physical adsorption. Restricted range of values for heat of adsorption, bT (?946.9 to 737.4 J/mol), was obtained from Temkin equation. Reduction in band intensities and vibrational changes observed in FTIR spectra indicate possible involvement of carbonyl (-C=O), carboxyl (-COOH), hydroxyl alcoholic (-OH) and amino (-NH2) functional groups on the adsorbents’ surfaces during the adsorption and interaction with the sulfonic acid groups (-SO3H) on the adsorbate molecules. The difference in irregular and porous texture surface morphology of fresh and dye-loaded adsorbents characterized the adsorption of the dyes by neem leaves. The study shows that neem leaves are potential alternative low-cost adsorbents for the effective removal of Congo red (CR) and Methyl orange (MO) from wastewater.

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Ibrahim, M. and Sani, S. (2015) Neem (Azadirachta indica) Leaves for Removal of Organic Pollutants. Journal of Geoscience and Environment Protection, 3, 1-9. doi: 10.4236/gep.2015.32001.

1. Introduction

Water is an essential for human survival and occupying 71% of the earth surface of which only about 0.05% is accessible for consumption. The bulk of the rest comprises of seawater, groundwater, swamps and frozen polar ice caps. Its demand doubles every 21 years globally, affecting 40% of world population. Thus, exploitation of safe water sources and water scarcity are global challenges that receive much attention from government and private organizations [1] [2].

Wastewaters, high in organic and inorganic materials (dyes, phenolic compounds, aromatic compounds and heavy metals) can be reclaimed from industrial effluents, municipal wastewater, agricultural return flows and storm water by different methods depending on its constituents [3]. The untreated effluents discharged from industries (textile, cosmetics, pulp and paper, paint, pharmaceutical, food, carpet and printing) are highly colored due to large amounts of unfixed dyes that remained during coloring and washing [4]. Almost all dyes in use today are synthetic with annual production of over 7 × 105 tonnes of which azo dyes account for 60% - 70% [5]. About 10-15% of these dyes are discharged as effluents during the dyeing process [6] [7]. The effluent could leach into surface and ground waters used for drinking; affect the photosynthesis of aquatic plants by hindering penetration of light into the water; and may cause suffocation of aquatic flora and fauna due to anaerobic degradation of azo dyes into highly lethal substances [8]-[10].

Most often the available techniques for removal of dyes from wastewaters are ineffective (or poorly employed), expensive, complicated, time-consuming and require highly-skilled personnel especially when the levels of dissolved dyes are in the range of 1 - 100 mg/L. This has stimulated the search for cheaper and easy to use alternatives [11]. Adsorption techniques (either batch or dynamic) have been found to be promising for pollutant removal from wastewaters [12] [13]. Thus, this work aimed at studying the adsorption behavior of neem leaves for the removal of Congo Red (CR) and Methyl Orange (MO) dyes.

2. Materials and Methods

2.1. Materials

Neem (Azadirachta indica) leaves were collected from twigs of a number of matured trees within and near the main campus of Umaru Musa Yar’adua University, Katsina. The leaves were excessively washed with tap-water followed by rinsing with distilled water to remove dust and any other soluble substances. They were allowed to air dry under shade at room temperature until they become crisp. The dried leaves were then pulverized with a mechanical grinder; and then dried overnight for 16 hours in an oven at a temperature range of 65˚C. The oven-dried samples was then sieved into the working size of 75 - 300 μm range using electronic shaker and the fractions preserved in separately labeled air-tight plastic containers for subsequent use [14].

Analytical grade (Congo Red and Methyl Orange) dyes from BDH were used as received without any purification. Stock solutions were prepared by dissolving 1 g of each dye in a 1000 cm3 volumetric flasks to make 1000 mg/L of the dye solution [15]. Working and calibration standards were prepared by seriel dilutions.

2.2. Methods

Fourier Transform Infra Red (FTIR) spectroscopy was conducted on both the raw adsorbent and the adsorbate loaded adsorbent using CARY 630 FTIR spectrophotometer from Agilent Technologies with the view to identify the different functional groups responsible for the adsorbate adsorption; and there possible changes thereafter. Similarly, Scanning Electron Microscopy (SEM) was carried out on the adsorbent before and after the adsorption using a Philips XL30 Scanning Electron Microscope at accelerating voltage of 15 kV, beam size 3.0, working distance 10 and magnification (2000×) in order to analyze possible changes on the morphological and surface characteristics of the adsorbent as a result of the adsorption process.

Batch adsorption studies were conducted by mixing various amounts of adsorbent (0.1 - 0.5 g) of different particle sizes (≥75 μm, ≤150 μm, ≤250 μm, ≤300 μm and >300 μm), in 250 cm3 Erlenmeyer flasks containing 50 cm3 of dye solution of known concentration (5 - 300 mg/L). The initial pH of the dye solutions were adjusted to the working values (pH 2 - 12) by adding few drops of 0.1 M HCl or 0.1 M NaOH aqueous solutions. The solutions were agitated using orbital shaker at 300 rpm and room temperature (30˚C ± 2˚C) for a series of contact time (5 - 120 min) to attain equilibrium. At the end of the equilibrium time intervals, the samples were taken out and the supernatant solution was separated from the adsorbent by filtration with Whatman No. 41 filter paper, discarding the first few volume (3 - 4 drops) of the filtrate [16]. The filtrates were used for analyses using UV- Visible spectrophotometer at λmax of 496.5 and 464 nm for congo red and methyl orange respectively, reporting each data point as an average value of triplicates readings. Percentage dye adsorption and equilibrium adsorption capacity, (mg/g) were evaluated using the equations;

(1)

(2)

where (mg/L) is the initial dye concentration, is the concentration at equilibrium or predetermined time t, (L) is the volume of dye solution used and W (g) is the weight of the adsorbent.

3. Results and Discussion

3.1. Agitation Time

Agitation time is an important parameter that affects all transfer phenomena including adsorption process [17]. With increased agitation time, the rate of diffusion of the dye molecules from bulk liquid to the liquid boundary layer surrounding the adsorbent particles becomes higher due to enhanced turbulence and decreased thickness of the liquid boundary layer [16].

Studies on the effect of agitation time (5 - 240 minutes) on the percent adsorption of the dyes (CR and MO) onto NLP adsorbent were carried out (Figure 1). On the onset of the process, the percent adsorption of both dyes onto NLP was rapid with CR attaining an optimum value of 99.70% in 15 minutes and an equilibrium value of 96.32% at 45 minutes. While MO attained an optimum value (83.33%) in 45 minutes and equilibrium value (64.79%) at 120 minutes.

According to Lian et al. [18] in his work for the adsorption of congo red onto Ca-bentonite surface, the relatively high removal of the dye initially by the adsorbent could be attributed to the availability of large number of vacant sites for adsorption of Congo red and methyl orange onto surfaces of the adsorbents. While at a later time, the process becomes relatively slower as it approaches equilibrium conditions until equilibrium is achieved at a given time [19]. At this time, the amount of the dye desorbing from the adsorbent is in a state of dynamic equilibrium with the amount of the dye being adsorbed, which reflects the maximum adsorption capacity of the adsorbent under the working conditions [19].

3.2. Effect of Adsorbent Dosage

Effects of adsorbents dosage (0.1 - 0.5 g) on percent adsorption of the dyes (Figure 2) revealed that the percent adsorption of CR onto the adsorbent varied from 75.10% - 91.57% while MO varied from 23.81% - 57.23%. As amount of adsorbent increases, number of active sites available for adsorption also increases, thus increasing the percent removal for the dyes. At the minimum dosage (0.1 g) there was diminutive availability of exchangeable sites which in turn led to removal of minimum amounts of dyes, while at maximum dosage (0.5 g) there was greater availability of exchangeable sites which ultimately led to the removal of maximum amounts of dyes [17].

3.3. Effect of Adsorbent Particle Size

Generally, as the adsorbent particle sizes decrease (from 300 μm to 75 μm) the surface area increases leading to incresaed adsorption of dye molecules (Figure 3). Percent adsorption of Congo red varied from 91.71% - 83.41%

Figure 1. Variation of % adsorption with agitation time.

Figure 2. Variation of % Adsorption with Adsorbent Dose.

Figure 3. Variation of % adsorption with particle size.

while that of methyl orange varied from 52.83% - 46.01%. This can be attributed to the fact that the larger particle sizes have widened diffusion path and decreased total surface area that lowers the ability of the dye to penetrate the entire internal pore structures of the adsorbents while the smaller particle sizes have shortened diffusion path and increased total surface area that makes the ability of the dye to penetrate all the internal pore structures of the adsorbents very high [16].

3.4. Effect of Initial Concentration

Studies on the effect of adsorbates loading concentration (5 - 300 mg/L) on the percent adsorption of the dyes (Figure 4) showed CR adsorption to increase (21.19% - 86.69%) from 5 to 100 mg/L and then slowly (86.69% -

Figure 4. Effect of variation of initial concentration of % adsorption.

90.48%) from 100 to 200 mg/L before it decreased to 82.43% at 300 mg/L loading concentration. Similarly, adsorption of MO indicated relatively rapid increase (12.87% - 90.14%) within the same range of initial concentrations.

This observation may be as a result of the fact that increase in concentration enhances the interaction between the dye and the adsorbent apart from providing the necessary driving force that overcomes the resistance to the mass transfer of the dyes from aqueous phase onto the surface of the adsorbents [16].

3.5. Effect of Initial pH

At lower pH (i.e. high H+ concentration) the percent adsorption as compared in Figure 5 showed removal of CR to increased fast from 88.39% at pH 2 to an optimum value of 93.70% at pH 7 and then decreased to 92.07 at pH 12. Similarly, percent adsorption of MO increased from 79.87% at pH 2 until it attained an optimum value of 87.92% at pH 4 and later decreased to 81.86% at pH 12. This observation of rapid increase in percent adsorption for the anionic dyes onto neem leaves were similar to that reported by Abdullah et al. [20] for the adsorption of anionic dyes such as methyl orange onto Lapindo volcanic mud (LVM). The variations in the pH values from acidic to alkaline medium makes both the degree of ionization of dye molecules and the surface properties of the adsorbent to vary which in turn affect the adsorption rate of dyes. Therefore, performing the adsorption in the acidic medium would increase the positive charge on the adsorbent surface causing an increase in the electrostatic attraction between anionic dye molecules (CR-dye- and MO-dye-) and the surface of adsorbents; hence, the increased rate of adsorption of the dyes (CR and MO).

On the other hand, the presence of high concentration of hydroxyl ions (OH-) on the adsorbents in the basic medium at pH range of 8 - 12 compete effectively with the dye molecules leading to decreased percent adsorption for both dyes onto the surface of the adsorbent.

3.6. Adsorption Isotherms

Based on the various linear relationship of the different isotherms tested (Figures not Included) adsorption isotherm parameters were calculated and tabulated in Table 1.

As shown in the table, the values of linear regression coefficient (𝑅2) for Langmuir isotherm are located in the range of 0.9989 - 0.9998, suggesting that the experimental data follow the Langmuir monolayer adsorption [21]. The calculated RL values varies in the order NLP-MO (−0.0250) < NLP-CR (−0.0078) in either case, the negative value shows unfavourable adsorption process [22] [23]. This may be attributed to the decrease in adsorption capacity of adsorbent brought about by decrease in charge density of the dyes during adsorption [24]. The mean values of monolayer adsorption capacity qm were found to increase in the order NLP-MO (21.23 mg/g) < NLP-CR (24.81 mg/g) which are generally lower than values in the range 41.24 - 128.26 mg/g for the removal of Congo red from aqueous medium onto neem leaves [22] and 404.4 mg/g for removal of methyl orange onto Pine-cone activated carbon [25]; higher than 5.94 mg/g for the adsorption of Congo red onto kaolin [26]; it is comparable to 20.5 mg/g and 21mg/g for adsorption of methyl orange onto orange peel and banana peel respect- tively; 22.86 mg/g for adsorption of Congo red onto burnt clay [27] and 20.20 for Congo red adsorption onto algae Valoria bryopsis carbon [28].

The regression coefficient (𝑅2) for the Freundlich isotherm ranged between 0.9910 - 0.9956; and the values of nF were both greater than 1 demonstrating that the experimental data fitted well to the Freundlich isotherm. The

Figure 5. Effect of Initial pH of the Adsorbate on % Adsorption.

Table 1. Adsorption Isotherm Parameters for theAdsorption of CR and MO by Neem Leaves.

adsorption process is said to be favourable, non-specific adsorption on heterogeneous surfaces [21] [29].

The relevant Temkin isotherm parameters (Table 1) indicate that the values of 𝑅2 are positioned within 0.9932 - 0.9937, which gave a close fit for the CR and MO adsorption onto the adsorbent. Furthermore, it can also be observed that the adsorption heat was restricted within −0.5362 to 0.7374 kJ/mol.

The Dubinin-Radushkevich (D-R) isotherm plot was obtained corresponding to which the isotherm parameters are calculated and summarized in Table 1. The values of linear regression coefficient (𝑅2) are in the range of 0.9359 - 0.9724, revealing that the experimental data fitted well with the Dubinin-Radushkevich (D-R) isotherm model. Moreover, it is reported that, when the value of 𝐸 is below 8 kJ/mol, the adsorption process can be considered as the physical adsorption. In contrast, if the value of 𝐸 is located in the range of 8 - 16 kJ/mol, it is the chemical adsorption. From the table, it can be observed that the obtained values of mean free energy, 𝐸, are limited within the range of 0.0791 - 0.3162 kJ/mol. Based on these data, it can thus be concluded that the effect of physical adsorption will play a dominating role in the adsorption process of CR and MO dyes onto the neem leaves derived adsorbents [21].

The correlation coefficient (R2) values are a measure of goodness-of-fit. For the adsorption process from Harkins-Jura isotherm plot, the values of R2 decrease in the order NLP-CR (0.9889) > NLP-MO (0.9837). The R2 values are generally good showing that the data fits the Harkins-Jura’s linear model very well. Harkin-Jura adsorption isotherm accounts for multilayer adsorption and can be explained by the existence of a heterogeneous pore distribution [29].

The FTIR spectrum of the adsorbent before adsorption (Figure 6(a)) display a number of absorption peaks, characterizing the complexity and heterogeneity of its surface [16]. The bands at 3448 cm?1 representing bonded OH in the oxygen-containing functional groups. The positions of the C?H (2920 cm?1), aliphatic C?C (1273 cm?1) and aromatic C=C (1604 cm?1) and carboxylic/carbonyl (1723 cm?1) groups vibrations contributed by those in the structure of cellulose, hemicelluloses and lignin, which are common components of all plant materials, are indicated by the FTIR spectra of powdered neem-tree leaves [30].

The shifting or splitting of some peaks (changes in some vibration frequencies) after the adsorption process indicates chemical interaction taking place between the biomass and the dye [31].

Figures 7(a)-(c) elucidates the surface morphologies of the adsorbent before and after adsorption. Before

(a)(b)(c)

Figure 6. FTIR of Neem Leave Adsorbents: (a) (before adsorption); (b) and (c) (after Adsorption of Congo Red and Methyl Orange Respectively).

(a) (b) (c)

Figure 7. (a) NLP Before adsorption; (b) NLP After Adsorption of CR; (c) NLP After Adsorption of MO.

contact with the adsorbate the surface appears as a fibrous material with irregular macropores and some expanded cavities which may allow for the diffusion of the dye molecules through the macropores of the adsorbent. After the adsorption, the appearance of molecular cloud over the surface of adsorbent confirms the binding of dye ions onto the functional groups present in neem leave [31].

4. Conclusion

The research findings revealed the adsorption capabilities of the substrate and that the adsorption process may involved diffusion of the dye molecules into the adsorbent as observed from the SEM.

Conflicts of Interest

The authors declare no conflicts of interest.

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