Document Type : Research papers
Authors
1 Water Purification Company, Alexandria, Egypt
2 Faculty of Agriculture (Saba Basha), Alexandria University
Abstract
Keywords
The use of low-cost adsorbents has been investigated for heavy metals removal from wastewaters as a replacement for costly current methods. In general, an adsorbent can be assumed as “low cost” if it requires little processing, is abundant in nature, or is a by-product or waste material from industry (Bailey et al., 1999). Heavy metals are often discharged by a number of industries, such as metal plating facilities, mining operations and tanneries. This can lead to the contamination of freshwater and marine environment (Low and Lee, 2000). It is well known that some metals such as antimony, chromium, copper, lead, manganese mercury, cadmium, etc., are significantly toxic to human beings and ecological environments (Doris et al., 2000). Generally, the techniques employed for heavy metal removal include precipitation, ion exchange, adsorption, filtration, electrode position, reverse osmosis (Rao et al., 2000). However, most of these techniques do not lead to a satisfactory depollution of metal ion considering the operational costs (Marchetti et al., 2000). Adsorption on solid-solution interface is an important means for controlling the extent of pollution due to heavy metal ions. Interest has recently arisen in the investigation of some unconventional methods and low cost materials for scavenging heavy metal ions from waste waters (Gloaguen and Morvan, 1997). In recent years, many materials as coconut shells (Crisafully et al.,2008), rice husk (Kishore et al., 2008), zeolite (Mamba et al., 2009), phosphate rock (Ma and Rao, 1999), tea and coffee waste (Amarasinghe and Williams, 2007), peanut shells (Qin et al., 2007), saw dust (AjayKumar et al., 2008), activated carbon (Gulnaziya et al., 2008), dry tree leaves and barks (Benhima et al., 2008)and orange peel (Ferda and Selen, 2012); have been investigated for the elimination of heavy metals from waste water .The objective of this study is to contribute in the search for less expensive adsorbents and their utilization possibilities for the removal of heavy metals (Cd, Cu, Ni, Zn, Cr and Pb) from aqueous solutions.
Materials and Methods
Sorbent materials:
Sorption studies have been focused on the use of low- cost sorbent materials. The first one is sugar beet pulp which is the by- product of sugar industry and it has been supplied from El Nile Sugar Factory, Egypt. It was milled and dried at 100°C throughout 24 h, then screened, washed with distilled water and dried at 65 oC for 1 h and passed through 0.4 mm sieved and kept for experimental study. The organic matter content in this material was 94% as determined by the method described by Allison (1965). The second sorbent is sawdust which was collected from a workshop in Alexandria city and sieved through a set of laboratory sieves and the fraction < 0.4 mm was used in the sorption experiments. The sawdust organic carbon was 46 % as determined by the method of Allison (1965). The third one is a low grade rock phosphate which was obtained from a sedimentary phosphate rock deposit supplied in a fine powder (passed through 38 mm standard sieve) from Al Ahram Mining and Natural Fertilizer Company, Egypt. Chemical composition of the rock phosphate is presented in Table 1. The forth sorbent was the (Zeolite) which purchased from Alex. for Import and Export with particle size of less than 0.6 mm. The chemical composition of zeolite is presented in Table 2.
Table (1). The chemical composition of rock phosphate
Constituents |
Concentration ,% |
P |
10.863 |
Ca |
28.123 |
Si |
6.071 |
Cd |
1.053 |
Pb |
4.021 |
Na |
0.668 |
Fe |
0.871 |
K |
0.108 |
Mn |
0.036 |
Cl |
0.570 |
L.O.I. |
16.560 |
L.O.I.=Loss on ignition
sours: Al Ahram Mining and Natural Fertilizer Company, Egypt.
Table (2). The chemical composition of zeolite
Weitght,% |
composition |
68.03 |
Sio2 |
0.21 |
Ti02 |
11.92 |
Al203 |
1.77 |
Fe203 |
0.01 |
MnO |
0.83 |
MgO |
2.65 |
CaO |
1.96 |
Na2O |
2.26 |
K20 |
10.25 |
H2O |
0.06 |
P2O5 |
0.05 |
AO3 |
Sours: from Alex for Import and Export.
Single metal sorption experiments:
A fixed amount of dry sorbent material (2 g) with 40 ml of metal solution were placed in a 100 ml volumetric flask and shaken at 200 rpm using a temperature controlled incubator shaker at 25±2oC.. The used metal ion concentrations were in the range of 5-400 mg/l (Cd2+ and Ni2+ ), 25-400 mg/l (Cu2+, Zn2, and Cr2+) and 50-700 mg/l (Pb2+ ) . Stock solutions (1000 mg/L) of cadmium, lead, zinc, chromium, Nickel and copper were prepared by metal nitrate salts in CaCl2 (0.01F) and the required concentrations were obtained by diluting the stock solutions (Shaheen et al., 2013). The contact time for batch tests was 2 h. Then, the aqueous /sorbent systems were filtered using Filter paper NO. (1) to remove any fine particles and the concentration of metal ions was determined using atomic absorption spectrophotometer (Schimadzu 6800). Each experiment was carried out in duplicate and the average results are presented. The initial and final metal concentrations in the solutions were determined by AAS. The sorption capacities of the sorbents were calculated after equilibrium was attained. The metal uptake capacity for each sample was calculated according to a mass balance of the metal ion using the following equation:
Where; m is the mass of adsorbent (g), V is the volume of the solution (L), Co is the initial concentration of metal (mg L-1), Ce is the equilibrium metal concentration (mg L-1) and qe is the quantity of metal adsorbed at equilibrium (mg/g). The percent removal of metals from the solution was calculated by the following equation:
The Langmuir and Freundlich adsorption isotherms were used to investigate the adsorption process of Cd, Ni, Cu, Cr, Zn and Pb on sawdust, sugar beet pulp, zeolite and phosphate rock adsorbents. The Langmuir adsorption isotherm model is given by Demiral et al. (2008) as follows:
The linearization of it gives the following form:
Where Ce, equilibrium metal concentration, qm and KL are the Langmuir constants related to maximum adsorption capacity (mg g-1), and the relative energy of adsorption (1/mg), respectively. Freundlich isotherm model is one of the most widely used mathematical models which fit the experimental data over a wide range of concentration. The Freundlich equation is given by Singh et al. (2011) as follows:
The logarithmic form of the equation is:
Where; qe is the amount of metal ion adsorbed per specific amount of adsorbent (mg g-1), Ce is equilibrium concentration (mgL-1), KF and n are Freundlich equilibrium constants.
Results and Discussion
Sorption capacity of sorbents
Tables 3 and 4 show the effect of varying initial concentration of Cd, Ni, Cu, Cr, Zn and Pb on the sorption capacity of the sorbent and the removal percentage for each single solution. It is clear that when the initial concentration of Cd and Ni ions is increased from 5 to 400 mg/L, the amount of sorbed metal per unit weight of the sorbent (mg/g) is increase, where as the removal percentage is decrease with the tested sorbents. The range of Cd sorption increased from 0.03 to 0.63 mg/g on sawdust, 0.02 to 1.57 mg/g on sugar beet pulp, 0.06 to 1.79 mg/g on zeolite and 0.04 to 1.35 mg/g on rock phosphate. The corresponding values on Ni were 0.05 to 0.50 mg/g on sawdust, 0.04 to 1.34 mg/g on sugar beet pulp, 0.04 to 1.26 mg/g on zeolite and 0.02 to 0.64 mg/g for rock phosphate.
To evaluate the effect of initial metal ion concentration on adsorption/sorption behavior of Cu, Zn and Cr ions, studies were conducted with initial concentrations of 25, 50, 75, 100, 125, 200, 300, and 400 mg/L. Tables 5, 6 and 7 show the effect of varying concentration of Cu, Zn and Cr on sorption capacity and removal percentage of each metal ion. It is clear that when the initial concentrations of metal ions is increased from 25 to 400 mg/L, the amount of sorbed metal per unit weight of the adsorbent (mg/g)is increased, as where the percentage removal is decreased with the tested sorbents. The range of Cu sorption increased from 0.31 to 3.49 mg/g on sawdust, 0.45 to 5.95 mg/g on sugar beet pulp, 0.42 to5.09 mg/g on zeolite and 0.47 to 5.75 mg/g on rock phosphate. The corresponding values for Cr sorption increased were from 0.23 to 2.40 mg/g on sawdust, 0.32 to 3.99 mg/g on sugar beet pulp, 0.40 to 4.39 mg/g on zeolite and 0.46 to 5.56 mg/g on rock phosphate. Also, the corresponding values for Zn adsorption were from 0.18 to 2.41 mg/g on sawdust, 0.24 to 3.05 mg/g on sugar beet pulp, 0.24 to 3.50 mg/g on zeolite and 0.33 to 3.32 mg/g on rock phosphate.
With respect to Pb ion adsorption/sorption, the studies were conducted with initial concentration of 50, 100, 200, 300, 400, 500, 600 and 700 mg/L. Table 8 show that as the initial concentration of Pb ion is increased from 50 to 700 mg/L, the amount of sorbed metal per unit weight of the adsorbent (mg/g) is also increased, where as the percentage removal has been decreased with the tested sorbents. The range of Pb ion increased from 0.03 to 0.06 mg/g on sawdust, 0.74 to 1.80 mg/g on sugar beet pulp, 0.88 to 2.40 mg/g on zeolite and 0.81 to 6.14 mg/g on rock phosphate. Tables (3-8) indicated that the higher sorptive capacities of adsorbents were found to take place at higher concentrations. This may be due to the interaction of all metal ions present in the solution with binding sites (Azouaou et al., 2010).The number of ions adsorbed from a solution of higher concentrations is more than that removed from the low concentrated solutions. It is observed also that the percentages of removal decreased with increasing the initial metal concentrations. The low sorption, at higher metal concentration, is due to the increased ratio of initial number of moles of Cd, Ni, Cu, Cr, Zn and Pb to the vacant sites available. For a given adsorbent Cu, Cr , Zn the total number of the available adsorbent sites was fixed thus adsorbing almost equals amount of adsorbate resulted in a decrease in the removal of adsorbate, consequent to an increase in initial concentrations of Cd, Ni, Cu, Cr, Zn and Pb concentrations. Therefore it is evident from the obtained results that each Cd, Ni, Cu, Cr, Zn and Pb metal ion adsorption is dependent on the initial metal concentration.
Tables (3and 4) show how the removal percentage of Cd and Ni ions varied as the initial metal concentration varied. Variation of the initial concentration from 5 to 400 mg/L decreased the removal percentage of Cd or Ni by all the tested adsorbent materials. The results showed that zeolite performed better at higher and lower concentration of Cd ion than the adsorbents used in this study. This is probably due to the presence of large number of binding sites on the surface of zeolite than the other adsorbents, used in this study. On other hand, the results showed that sugar beet pulp performed better at higher concentration of Ni ion than is the other adsorbents while zeolite was better at low concentrations and this is probably due to the large number of binding sites in zeolite.
Tables (5, 6 and 7) showed that the removal percentage of Cu, Cr and Zn ions varied as the initial metal concentration varied. Variation of the initial concentration from 25 to 400 mg/L decreased the percentage removal of Cu, Cr or Zn by the tested absorbents .The results also showed that rock phosphate performed better at higher and lower concentration of Cu and Cr ions than the other adsorbents used in this study. On other hand, the results showed that zeolite performed better at the higher concentration of Zn ion than the other adsorbents while rock phosphate was better at all the concentrations except at the higher concentration of Zn (400 mg/L). Table 8 shows that the removal percentage of Pb ions varied as the initial metal concentration varied. Variation of the initial concentration from 50 to 700 mg/L decreased the percentage removal of Pb by all the tested materials. The results also showed that rock phosphate performed better at higher concentrations of Pb ion than the other adsorbents. On other hand, the results showed that zeolite performed better at lower concentrations of Pb ion.
Table (3). Effect of initial concentration of cadmium on its adsorption by sawdust, sugar beet pulp, zeolite and rock phosphate adsorbents
Sorbent material |
Initial conc. (mg Cd/L) |
Final conc. (mg Cd/L) |
Sorption capacity (mg Cd/g of sorbent) |
Removal (%) |
|
5 |
3.50 |
0.03 |
30.00 |
|
10 |
8.02 |
0.03 |
19.80 |
|
20 |
15.42 |
0.09 |
22.90 |
Sawdust |
40 |
29.64 |
0.20 |
25.90 |
|
80 |
62.60 |
0.34 |
21.70 |
|
100 |
82.44 |
0.35 |
17.56 |
|
200 |
165.40 |
0.69 |
17.30 |
|
300 400 |
268.50 368.50 |
0.63 0.63 |
10.50 7.87 |
|
5 |
3.49 |
0.03 |
30.10 |
|
10 |
7.10 |
0.05 |
29.00 |
|
20 |
14.40 |
0.11 |
28.00 |
Sugar beet pulp |
40 |
28.96 |
0.22 |
27.60 |
|
80 |
58.70 |
0.42 |
26.60 |
|
200 |
150.24 |
0.99 |
24.88 |
|
300 |
237.50 |
1.25 |
20.83 |
|
400 |
321.17 |
1.57 |
20.20 |
|
5 |
1.55 |
0.06 |
69.00 |
|
10 |
3.19 |
0.13 |
68.10 |
|
20 |
8.45 |
0.23 |
57.75 |
Zeolite |
40 |
18.40 |
0.43 |
54.00 |
|
80 |
40.60 |
0.78 |
49.25 |
|
200 |
138.60 |
1.22 |
30.70 |
|
300 |
208.14 |
1.83 |
30.00 |
|
400 |
310.16 |
1.79 |
22.50 |
|
5 |
2.55 |
0.04 |
49.00 |
|
10 |
5.18 |
0.09 |
48.20 |
|
20 |
10.70 |
0.18 |
46.50 |
Rock Phosphate |
40 |
21.15 |
0.37 |
47.12 |
|
80 |
45.42 |
0.69 |
43.21 |
|
200 |
159.14 |
0.81 |
20.43 |
|
300 |
237.40 |
1.25 |
20.00 |
|
400 |
332.50 |
1.35 |
16.87 |
Table (4). Effect of initial concentration of nickel on its adsorption by sawdust, sugar beet pulp, zeolite and rock phosphate adsorbents
Sorbent material |
Initial conc. (mg Ni/L) |
Final conc. (mg Ni/L) |
Sorption capacity (mg Ni /g of sorbent) |
Removal (%) |
|
5 |
3.75 |
0.03 |
25.00 |
|
10 |
7.60 |
0.05 |
24.00 |
|
20 |
15.20 |
0.10 |
24.00 |
Sawdust |
40 |
30.60 |
0.19 |
23.50 |
|
80 |
63.50 |
0.33 |
20.62 |
|
100 |
78.32 |
0.43 |
21.60 |
|
200 |
178.14 |
0.44 |
10.93 |
|
300 400 |
275.18 375.00 |
0.50 0.50 |
8.22 6.25 |
|
5 |
3.22 |
0.04 |
35.60 |
|
10 |
6.20 |
0.08 |
33.00 |
|
20 |
13.80 |
0.12 |
31.00 |
Sugar beet pulp |
40 |
27.60 |
0.25 |
31.00 |
|
80 |
55.50 |
0.49 |
30.60 |
|
200 |
147.62 |
1.05 |
26.00 |
|
300 |
248.18 |
1.04 |
17.00 |
|
400 |
333.17 |
1.34 |
16.70 |
|
5 |
3.00 |
0.04 |
40.00 |
|
10 |
6.12 |
0.08 |
38.00 |
|
20 |
12.20 |
0.16 |
39.00 |
Zeolite |
40 |
25.55 |
0.29 |
36.25 |
|
80 |
52.71 |
0.55 |
34.11 |
|
200 |
164.60 |
0.71 |
17.92 |
|
300 |
254.17 |
0.92 |
15.27 |
|
400 |
337.16 |
1.26 |
15.71 |
|
5 |
4.00 |
0.02 |
20.00 |
|
10 |
8.06 |
0.04 |
19.40 |
|
20 |
16.20 |
0.08 |
19.00 |
Rock Phosphate |
40 |
32.50 |
0.15 |
18.75 |
|
80 |
64.80 |
0.30 |
17.00 |
|
200 |
178.45 |
0.43 |
10.77 |
|
300 |
275.38 |
0.49 |
8.20 |
|
400 |
368.22 |
0.64 |
7.94 |
Table (5). Effect of initial concentration of cupper on its adsorption by sawdust, sugar beet pulp, zeolite and rock phosphate adsorbents
Sorbent material |
Initial conc. (mg Cu/L) |
Final conc. (mg Cu/L) |
Sorption capacity (mg Cu /g of sorbent) |
Removal (%) |
|
25 |
9.18 |
0.31 |
63.28 |
|
50 |
20.00 |
0.60 |
53.38 |
|
75 |
34.38 |
0.81 |
54.00 |
Sawdust |
100 |
45.24 |
1.09 |
54.00 |
|
125 |
57.88 |
1.34 |
53.69 |
|
200 |
93.49 |
2.13 |
53.25 |
|
300 |
145.92 |
3.08 |
51.36 |
|
400 |
225.45 |
3.49 |
43.60 |
|
25 |
2.23 |
0.45 |
91.10 |
|
50 |
5.50 |
0.89 |
89.00 |
|
75 |
9.75 |
1.30 |
87.00 |
Sugar beet pulp |
100 |
13.38 |
1.73 |
86.60 |
|
125 |
24.98 |
2.00 |
80.00 |
|
200 |
40.42 |
3.19 |
79.79 |
|
300 |
77.80 |
4.44 |
74.06 |
|
400 |
120.24 |
5.59 |
69.89 |
|
25 |
3.94 |
0.42 |
84.24 |
|
50 |
8.93 |
0.82 |
82.14 |
|
75 |
17.79 |
1.14 |
76.28 |
Zeolite |
100 |
21.96 |
1.56 |
78.04 |
|
125 |
30.35 |
1.89 |
75.72 |
|
200 |
52.50 |
2.95 |
73.75 |
|
300 |
95.82 |
4.08 |
68.06 |
|
400 |
145.40 |
5.09 |
63.65 |
|
25 |
1.39 |
0.47 |
94.44 |
|
50 |
2.22 |
0.95 |
95.44 |
|
75 |
4.52 |
1.40 |
93.97 |
Rock Phosphate |
100 |
5.08 |
1.89 |
94.92 |
|
125 |
5.16 |
2.39 |
95.87 |
|
200 |
28.45 |
3.43 |
85.77 |
|
300 |
62.25 |
4.75 |
79.25 |
|
400 |
112.24 |
5.75 |
71.94 |
Table (6). Effect of initial concentration of chromium on its adsorption by sawdust, sugar beet pulp, zeolite and rock phosphate adsorbents
Sorbent material |
Initial conc. (mg Cr/L) |
Final conc. (mg Cr/L) |
Sorption capacity (mg Cr /g of sorbent) |
Removal (%) |
|
25 |
13.26 |
0.23 |
46.96 |
|
50 |
27.85 |
0.44 |
44.30 |
|
75 |
42.72 |
0.65 |
43.04 |
Sawdust |
100 |
60.60 |
0.79 |
39.40 |
|
125 |
80.60 |
0.89 |
35.52 |
|
200 |
132.25 |
1.36 |
33.87 |
|
300 |
204.22 |
1.92 |
31.92 |
|
400 |
280.20 |
2.40 |
29.95 |
|
25 |
9.24 |
0.32 |
63.04 |
|
50 |
18.63 |
0.63 |
62.74 |
|
75 |
29.36 |
0.91 |
60.80 |
Sugar beet pulp |
100 |
40.80 |
1.18 |
59.20 |
|
125 |
56.40 |
1.37 |
54.88 |
|
200 |
97.24 |
2.06 |
51.38 |
|
300 |
146.20 |
3.08 |
51.26 |
|
400 |
200.40 |
3.99 |
49.90 |
|
25 |
5.23 |
0.40 |
89.54 |
|
50 |
10.28 |
0.79 |
79.44 |
|
75 |
20.28 |
1.09 |
72.80 |
Zeolite |
100 |
32.60 |
1.35 |
67.40 |
|
125 |
44.60 |
1.61 |
64.32 |
|
200 |
73.60 |
2.53 |
63.20 |
|
300 |
123.20 |
3.54 |
58.93 |
|
400 |
180.40 |
4.39 |
54.90 |
|
25 |
2.12 |
0.46 |
91.51 |
|
50 |
4.24 |
0.92 |
91.52 |
|
75 |
10.68 |
1.29 |
85.52 |
Rock Phosphate |
100 |
16.00 |
1.68 |
84.00 |
|
125 |
20.60 |
2.09 |
83.92 |
|
200 |
42.72 |
3.15 |
78.64 |
|
300 |
80.40 |
4.39 |
73.20 |
|
400 |
122.25 |
5.56 |
69.43 |
Table (7). Effect of initial concentration of zinc on its adsorption by sawdust, sugar beet pulp, zeolite and rock phosphate adsorbents
Sorbent material |
Initial Conc. (mg Zn/L) |
Final Conc. (mg Zn/L) |
Sorption capacity (mg Zn /g of sorbent) |
Removal (%) |
|
25 |
16.10 |
0.18 |
35.60 |
|
50 |
34.30 |
0.31 |
31.40 |
|
75 |
51.24 |
0.48 |
31.66 |
Sawdust |
100 |
69.00 |
0.62 |
31.00 |
|
125 |
86.38 |
0.77 |
30.89 |
|
200 |
138.22 |
1.24 |
30.89 |
|
300 |
207.67 |
1.85 |
30.77 |
|
400 |
279.36 |
2.41 |
30.16 |
|
25 |
13.08 |
0.24 |
47.68 |
|
50 |
28.32 |
0.43 |
43.36 |
|
75 |
43.42 |
0.63 |
42.10 |
Suger beet |
100 |
59.00 |
0.82 |
41.00 |
pulp |
125 |
73.43 |
1.03 |
41.28 |
|
200 |
118.68 |
1.63 |
40.00 |
|
300 |
175.50 |
2.49 |
41.00 |
|
400 |
247.40 |
3.05 |
38.00 |
|
25 |
12.82 |
0.24 |
48.72 |
|
50 |
28.14 |
0.44 |
47.00 |
|
75 |
39.98 |
0.70 |
46.70 |
Zeolite |
100 |
53.42 |
0.93 |
46.58 |
|
125 |
67.50 |
1.15 |
46.00 |
|
200 |
109.42 |
1.81 |
45.29 |
|
300 |
169.22 |
2.62 |
43.59 |
|
400 |
225.24 |
3.50 |
43.69 |
|
25 |
8.45 |
0.33 |
66.20 |
|
50 |
17.30 |
0.65 |
65.40 |
|
75 |
26.25 |
0.98 |
65.00 |
Rock |
100 |
35.63 |
1.29 |
64.73 |
Phosphate |
125 |
46.26 |
1.57 |
62.99 |
|
200 |
102.75 |
1.95 |
48.62 |
|
300 |
156.40 |
2.87 |
47.86 |
|
400 |
234.22 |
3.32 |
41.44 |
Table (8). Effect of initial concentration of lead on its adsorption by sawdust, sugar beet pulp, zeolite and rock phosphate adsorbents
Sorbent material |
Initial conc. ( mg Pb/L) |
Final conc. (mg Pb/L) |
Sorption capacity (mg Pb /g of sorbent) |
Removal (%) |
|
50 100 |
49.00 98.60 |
0.02 0.03 |
2.00 1.40 |
|
200 |
198.10 |
0.04 |
0.95 |
|
300 |
297.82 |
0.04 |
0.73 |
Sawdust |
400 |
397.40 |
0.05 |
0.65 |
|
500 |
496.92 |
0.06 |
0.62 |
|
600 |
598.00 |
0.04 |
0.40 |
|
700 |
697.00 |
0.06 |
0.42 |
|
50 |
13.07 |
0.74 |
73.86 |
|
100 |
66.40 |
0.67 |
33.60 |
|
200 |
145.40 |
1.09 |
27.30 |
Sugar beet |
300 |
228.40 |
1.43 |
23.86 |
pulp |
400 |
323.28 |
1.53 |
19.18 |
|
500 |
415.60 |
1.69 |
16.88 |
|
600 |
512.14 |
1.76 |
14.64 |
|
700 |
610.12 |
1.80 |
12.84 |
|
50 |
6.15 |
0.88 |
87.70 |
|
100 |
20.50 |
1.59 |
79.50 |
|
200 |
95.60 |
2.09 |
52.20 |
Zeolite |
300 |
162.60 |
2.75 |
45.80 |
|
400 |
240.00 |
3.20 |
40.00 |
|
500 |
368.66 |
2.63 |
26.27 |
|
600 |
485.00 |
2.30 |
19.16 |
|
700 |
580.00 |
2.40 |
17.14 |
|
50 |
9.42 |
0.81 |
81.16 |
|
100 |
20.62 |
1.59 |
79.38 |
|
200 |
45.40 |
3.09 |
77.30 |
Rock |
300 |
106.40 |
3.87 |
64.53 |
Phosphate |
400 |
136.20 |
5.28 |
65.95 |
|
500 |
205.14 |
5.90 |
58.97 |
|
600 |
338.26 |
5.23 |
43.62 |
|
700 |
393.25 |
6.14 |
43.82 |
Mathematical quantifying of metal sorption
To quantify the sorption capacity of the tested sorbents in relation to the concentration of Cd, Ni, Cu, Cr, Zn and Pb ions, the obtained experimental data were fitted to two isotherm models: Langmuir and Freundlich . The values of the various constants of the two models were calculated and represented in Table 9. This indicated that most of the experimental data fitted well to the two models. By comparing the determination coefficients (R2), it was observed that Freundlich isotherm gives a good model for the adsorption systems of all the tested metals with the tested adsorbents except lead with sawdust and zeolite. Also, Langmuir isotherm gives a good model for the adsorption systems of some metals with some sorbents, which is based on monolayer sorption on to the surface restraining finite number of identical sorption sites.
According to the linear form of Freundlich isotherm, the constant kf and 1/n were determined by linear regression from the plot of ln qe against ln Ce. Kf is a measure of the degree or strength of adsorption. Low value of Kf indicates the more adsorption (Horsfall et al., 2006) while 1/n is used as an indication for the favorable of sorbent for removal of ions. The Freundlich constants kf and 1/n are adsorption capacity and adsorption intensity which are determined for Cd, Ni, Cu, Cr, Zn and Pb are summarized in Table 9. It can be observed from this table that the quantity 1/n is less than unity for Cd, Ni, Cu, Cr, Zn and Pb adsorption which indicates adsorption isotherm favorable for adsorptive removal of Cd, Ni, Cu, Cr, Zn and Pb. The results for Cd, Ni, Cu, Cr, Zn and Pb were well represented by the linear form of Freundlich isotherms model using the four tested sorbents except Pb using sawdust and zeolite.
When the Langmuir isotherm model was applied to the obtained data of the six metals, the constants qm and KLthese were determined from Ce/q versus Ce plot. These constants do not explain the chemical or physical properties of the adsorption process; However, the model represens the equilibrium data and indicates that there was formation of a monolayer of metal ions on the surface of the tested sorbents. A reasonable fit was obtained for the equilibrium data of both Cd, using zeolite rock phosphate and sawdust, Ni using all sorbents, Cu using sugar pulp, zeolite and rock phospate, Cr using all sorbents, Zn using rock phosphate and sawdust and Pb using all sorbents (Table 9). When application of Langmuir model, to the equilibrium data of Cd using sugar beet, Zn using (sugar beet pulp and zeolite), the Langmuir model resulted in a large deviation from experimental data and unreasonable values of R2. Howevere, a very good fit for Ni sorption by the four tested sorbents was obtained using Freundlich and Langmuir models (Table 9 and Figs. 1 and 2).
The higher the KL, the higher is the affinity of the adsorbent for metal ions, qm can also be interpreted as the total number of binding sites that are available for adsorption (Volesky, 1995). According to Table 9, the affinity for Cd can be arranged in the under zeolite > rock phosphate >sawdust >sugar beet pulp, for Ni: is sawdust > zeolite > rock phosphate > sugar beet pulp, for Cu: is rock phosphate > sugar beet pulp > zeolite> sawdust, for Cr :is rock phosphate > zeolite > sugar beet pulp > sawdust, for Zn: is rock phosphate > sugar beet pulp > zeolite > sawdust and for Pb :is rock phosphate > zeolite > sugar beet pulp >sawdust.
In conclusion, the sorption performances of Cd , Ni, Cu, Cr and zn are strongly affected by initial metal concentrations and sorbent material type. The obtained results confirmed that the tested sorbents as a low cost materials are able to reduce the tested ion concentrations in aqueous solutions, suggesting that sugar beet pulp, zeolite and rock phosphate could be used as a cost- useful op tion to remediate heavy metals contaminated waters.
Fig (1). Langmuir adsorption isotherm for Ni adsorption
Fig (2). Freundlich adsorption isotherm for Ni adsorption.
Table (9). Parameters and determination coefficient of Cd, Ni, Cu, Cr, Zn and Pb removal data according to the degree of correlation of Langmuir and Freundlich equations
Metal type |
Sorbent material |
Langmuir parameters |
Freundlich parameters |
||||
qm (mg/g) |
KL (L/mg) |
R2 |
1/n |
Kf |
R2 |
||
Cd |
Sawdust Sugar beet pulp Zeolite Rock Phosphate |
1.06 5.47 2.16 1.60 |
0.0068 0.0013 0.0155 0.0122 |
0.8512 0.4173 0.9672 0.9465 |
0.7902 0.9573 0.6187 0.6570 |
0.0107 0.0077 0.0630 0.0361 |
0.9631 0.9844 0.9850 0.9520 |
Ni |
Sawdust Sugar beet pulp Zeolite Rock Phosphate |
0.65 1.98 1.46 0.86 |
0.0127 0.0056 0.0090 0.0062 |
0.9621 0.9455 0.9249 0.9633 |
0.7269 0.7798 0.6883 0.7772 |
0.0124 0.0171 0.0244 0.0082 |
0.9380 0.9830 0.9670 0.9680 |
Cu |
Sawdust Sugar beet pulp Zeolite Rock Phosphate |
8.40 7.36 7.97 6.28 |
0.0034 0.0216 0.0113 0.0672 |
0.7977 0.9411 0.9514 0.9835 |
0.8126 0.6186 0.6981 0.4932 |
0.0483 0.3043 0.1697 0.6598 |
0.9858 0.9904 0.9930 0.8840 |
Cr |
Sawdust Sugar beet pulp Zeolite Rock Phosphate |
4.50 8.55 6.52 7.07 |
0.0036 0.0039 0.0097 0.0233 |
0.9024 0.8520 0.8888 0.9463 |
0.7453 07953 0.6541 0.5932 |
0.0361 0.0581 0.1473 0.3308 |
0.9960 0.9950 0.9880 0.9903 |
Zn |
Sawdust Sugar beet pulp Zeolite Rock Phosphate |
18.51 13.83 25.13 4.70 |
0.0004 0.0012 0.0007 0.0094 |
0.4068 0.6183 0.4650 0.9561 |
0.9778 0.8961 0.9447 0.6639 |
0.0062 0.0223 0.0210 0.1005 |
0.9990 0.9970 0.9970 0.9600 |
Pb |
Sawdust Sugar beet pulp Zeolite Rock Phosphate |
0.06 2.05 2.73 6.82 |
0.0087 0.0107 0.0116 0.0163 |
0.8028 0.9747 0.9391 0.9744 |
0.3391 0.2785 0.2217 0.3262 |
0.0062 0.2960 0.7222 0.3262 |
0.6950 0.8340 0.7700 0.9190 |