Document Type : Original Research Paper
Authors
1 Department of Chemistry, Yazd University, Yazd, Iran
2 Department of Chemistry, Ayatollah Alozma Boroujerdi University, Boroujerd, Iran
Abstract
Keywords
INTRODUCTION
As a result of industrial development, increasing urban sewage and industrial pollution with toxic compounds has become a main concern. Among the toxic substances, released by industrial activities, heavy metals threaten aquatic life the most, owing to their non-degradable nature, severe toxicity, and carcinogenicity and aggregation capabilities (Ok et al., 2007). Mercury is one of the heavy metals and very toxic. Mercury compounds are toxic and incomposible contaminations in environment (Farooq et al., 2010). Mercury is classified into three main groups: elemental, inorganic, and organic mercury (Bernhoft, 2012). Elemental mercury is used in thermometer, metallurgy, mining, gold extraction, and dentistry (Nriagu et al., 1992; Pestana & Formoso, 2003). It is poorly absorbed, presenting little health risk, yet in the vapor form, metallic mercury is readily absorbed through the lungs and can cause body damage (Houston, 2007). Inorganic mercury compounds, such as mercury salts, result from the combination of mercury with chlorine, sulfur, or oxygen. Mercuric chloride (HgCl2), used as a preservative for photographic development, is highly toxic and corrosive; mercury sulfide (HgS) is often used as a pigment in paints due to its red color; and mercury fulminate (Hg(CNO)2) is used as an explosive detonator (Azevedo et al., 2012; Geier & Geier, 2003). Like elemental mercury, the inorganic one in the blood stream binds to erythrocytes and amino acids, disrupting their activities, causing glutathione or metallothionein, or it is transported suspended in plasma (Ballatori & Clarkson, 1985; Grandjean et al., 1997). Organic mercury compounds result from a covalent bond between mercury and carbon atoms of an organic functional group such as a methyl, ethyl, or phenyl group. Methyl mercury is often formed by methylation of inorganic mercuric ions by soil and water micro-organisms (Zalups, 2000; Clarkson & Magos, 2006; Rooney, 2007). The highest amount of a mercury compound to exist in human body is in the form of methyl mercury, which usually enters human body by eating fish (Namasivayam & Kadirvelu, 1999; Bae et al., 2001).
High exposure to mercury induces changes in the central nervous system, potentially resulting in irritability, fatigue, behavioral changes, tremors, headaches, hearing and cognitive loss, dysarthria, incoordination, and hallucinations (Azevedo et al., 2012). Also, the mercury compounds harm the liver and kidneys, causing some disorder in enzymic activity, resulting in illness and death (Wagner-Dobler et al., 2000; Boening, 2000) .
Several methods have been proposed to remove mercury from water (Saglam et al., 1999; Hunsom et al., 2005; El-Samrani et al., 2008; Yun et al., 1993; Dabrowski, 2001; Ozaki et al., 2002; Yaghmaeian et al., 2015; Rahmanzadeh et al., 2016; Wang et al., 2016). These methods must be considered in terms of their feasibility and cost, in addition to the acceptable impact of the removing the mentioned material. Adsorption is a useful method to remove mercury ions from aqueous solutions (Fu & Wang, 2011). In this study, mercury ions, in the form of Hg (I) and Hg (II) ions, in aqueous solutions are adsorbed by titanium dioxide nanoparticles, for the first time.
MATERIALS AND METHODS
Mercry (I) nitrate (Hg2(NO3)2.2H2O) and Mercury (II) nitrate (Hg(NO3)2.H2O) were purchased from Merck, Germay. Titanium dioxide nanoparticles (Rutile/Anatase: 85/15, Purity: >99%, Average Particle Size (APS): 20 nm, Spechfic Surface Area (SSA): >30 m2/g) were prepared from Degussa. In the experiment, 50 ml of Hg (I) and Hg (II) ions solution with a certain concentration, determined via dilution of the stock solution, was poured into a 100 ml flask. In order to adjust the solution' pH, we used optimum amount of NaOH or HCl 1, i.e. 0.5 or 0.01 M solution. Then, a given mass of TiO2 nanoparticles was added to each flask and the resultant suspension was shaken in a thermostatic orbit incubator shaker for 45 min. Once completed, a sample of the suspension was removed from the flask and filtered with a filter paper to separate adsorbent particles. The filtrate was analyzed for residual Hg(I) and Hg(II) ions . The adsorption percentage (% adsorption) was determined as:
(1)
where Ci (mg/L) is the initial concentration of Hg(I) and Hg(II) ions and Cf (mg/L), the final concentration of Hg(I) and Hg(II) ions in the solution. The quantity of mercury ions adsorbed per unit mass of adsorbent (qe) was obtained, using Equation (2) (Fakhri, 2015).
(2)
where Ci is the initial concentration of Hg(I) and Hg(II) ions and Ce (mg/L), the equilibrium concentration of Hg(I) and Hg(II) ions in the solution. The solution's volume is represented with v (L) while m (g) stands for the adsorbent's mass.
RESULTS AND DISCUSSION
One of the most important parameters in adsorption process is the initial pH of the solution. For mercury ions (I) and (II), this value altered between 1 and 11. Figure 1 shows the results, based on which, adsorption percentage of Hg (I) and Hg (II) ions ascends as the initial pH of the solution rises, hence at pH=1, the lowest adsorption percentage and at pH=9 and 7, the highest adsorption percentage were obtained for mercury ions (I) and (II), respectively. The reason can be expressed based on the percentages of hydronium ions in the solution. In other words, when pH is low, the concentration of H+ ions is high and the competition between H+, Hg+, and Hg2+ ions for adsorption onto the adsorbent surface causes the adsorption, itself, be decreased.But when pH is high, because of reduced H+ ions, these ions cannot compete with Hg+ and Hg2+ ions, hence the adsorption increases.
Fig. 1. The effect of initial pH of the solution on the adsorption percentage (constant conditions: initial concentration of the solution 50 mg/L for Hg(I) and 40 mg/L for Hg(II) , with particle size of 20 nm, temperature of 22 10C, contact time of 45 min, and adsorbent dosage of 0.05g)
For the purpose of studying nanoparticles size's effect on adsorption percentage, we utilized titanium dioxide nanoparticles, 20, 100, and 400 nm in size. The highest adsorption percentage was obtained for both mercury ions (I) and (II), with the adsorbent size of 20 nm (Fig. 2). The larger the size of TiO2 nanoparticles, the smaller the ratio of surface to volume and thus, the fewer the available sites for adsorption and subsequently the lower the adsorption. Available places for adsorption and contact region area of particles with absorbent surface of 20 nm nanoparticles are more than 100 and 400 nm, hence more iones are probable to be absorbed on the surface and will have maximum adsorption percentage.
Fig. 2. The effect of particle size on adsorption percentage (constant conditions: initial concentration of the solution = 50 mg/L for Hg(I) and 40 mg/L for Hg(II), pH=9 for Hg(I) and pH=7 for Hg(II), temperature=22 10C, contact time=45 min, and adsorbent dosage=0.05g)
Figure 3 illustrates the impact of TiO2 nanoparticles' quantity on the adsorption of mercury (I) and (II) ions. Results show that the amount of 0.05 g of titanium dioxide nanoparticles is optimal value for maximum adsorption of mercury (I) and (II) ions from the aqueous solution. The adsorption percentage ascends as the adsorbent quantity grows, which is due to the increase in effective collisions between mercury ions and TiO2 nanoparticles.
Fig. 3. The effect of adsorbent dosage on the adsorption percentage (constant conditions: initial concentration of the solution 50 mg/L for Hg(I) and 40 mg/L for Hg(II), pH 9 for Hg(I) and pH 7 for Hg(II), particle size 20 nm, contact time 45 min and temperature 22 1°C)
Figure 4 shows the impact of contact time on adsorption percentage of mercury (I) and (II) ions onto titanium dioxide nanoparticles, examined at 15, 30, 45, 60, 75, 90, and 105 minutes.
As seen, by increasing the contact time, the adsorption percentages of mercury (I) and (II) ions in the solution will ascend respectively, up to 75 minutes and 45 minutes, because mercury ions have more times for adsorption onto the absorbent.
Fig. 4. The effect of contact time on the adsorption percentage (constant conditions: initial concentration of the solution 50 mg/L for Hg(I) and 40 mg/L for Hg(II), pH 9 for Hg(I) and pH 7 for Hg(II), particle size 20 nm, temperature 22 1°C and adsorbent dosage 0.05g)
To evaluate the effect of temperature, the adsorption experiments were performed at different temperatures of 22°C, 35°C, 45°C, and 55°C. Figure 5 demonstrates the results. As it can be seen, the highest adsorption percentage was obtained for both mercury ions at temperature of 22°C. Adsorption percentage is reduced as the temperature increases, because adsorption process of mercury ions (I) and (II) on titanium dioxide nanoparticles is exothermic, similar to the most of adsorption processes.
Fig. 5. The effect of temperature on the adsorption percentage (constant conditions: initial concentration of the solution 50 mg/L for Hg(I) and 40 mg/L for Hg(II), pH 9 for Hg(I) and pH 7 for Hg(II), particle size 20 nm, contact time 75 min for Hg(I) and 45 min for Hg(II) and adsorbent dosage 0.05g)
The initial concentration of adsorbate is a factor that can affect the adsorption. As the data in Figure 6 show, the adsorption percentage is decreased by increasing initial concentration of Hg (I) and Hg (II) ions so that initial concentration of 50 and 40 mg/L is more satisfactory, respectively. The reason for this is that by increasing the adsorbate on absorbent, the adsorption sites saturate quickly and the adsorption is reduced.
Fig. 6. The effect of initial concentration of Hg (I) and Hg(II) ions on the adsorption percentage (constant conditions: pH=9 for Hg(I) and pH=7 for Hg(II), particle size=20 nm, temperature=22 1°C, contact time=75 min for Hg(I) and 45 min for Hg(II), and adsorbent dosage=0.05g)
When studying adsorption, in order to have fitting experimental results with theoretical models, adsorption isotherms have been used. Here, the used isotherms were Langmuir, Freundlich, and Temkin isotherms. This linear equations are (He et al., 2015; Mihaly-Cozmuta et al., 2014):
Langmuir equation: (3)
Freundlich equation: (4)
Temkin equation: (5)
where Ce (mg/L) is the equilibrium concentration of adsorbate in solution; qe (mg/g), the amount of adsorbate per unit mass of adsorbent; KL (L/mg), the Langmuir isotherm constant; qm (mg/g), the maximum adsorption capacity of Langmuir isotherm; KF (mg1-(1/n) L1/n /g), the Freundlich constant; and n, the intensity of adsorption. Furthermore, is a constant, depending on the adsorption heat and KT (L/g) is the Temkin isotherm constant.
For Langmuir isotherm, the plot of 1/qe versus 1/Ce gives a straight line, in which KL is determined by a slope ( ) and qm by an intercept (1/qm) (Fig. 7). For Freundlich isotherm, the plot of log qe versus log Ce gives a straight line in which n is determined by a slope (1/n) and KF by an intercept (logKF) (Fig. 8). Also, for Temkin isotherm, the plot of qe versus lnCe gives a straight line where B1 is determined by a slope (B1) and KT by an intercept (B1lnKT) (Fig. 9). Table 1 and 2 show the results.
Fig. 7. Langmuir adsorption isotherm for Hg (I) and Hg (II) ions onto TiO2 nanoparticles
Fig. 8. Freundlich adsorption isotherm for Hg (I) and Hg (II) ions onto TiO2 nanoparticles
Fig. 9. Temkin adsorption isotherm for Hg (I) and Hg (II) ions onto TiO2 nanoparticles
Table 1. Parameters of isotherms for Hg(I) ion, using TiO2 nanoparticles
|
Langmuir |
Freundlich |
Temkin |
||||||
|
KL (L/mg) |
qm (mg/g) |
R2 |
KF (mg1-(1/n)L1/n/g) |
n |
R2 |
KT (L/g) |
B1 |
R2 |
|
0.32 |
114.9 |
0.9626 |
26.4 |
2 |
0.8401 |
6.9 |
16.7 |
0.9266 |
Table 2. Parameters of isotherms for Hg(II) ion, using TiO2 nanoparticles
|
Langmuir |
Freundlich |
Temkin |
||||||
|
KL (L/mg) |
qm (mg/g) |
R2 |
KF (mg1-(1/n)L1/n/g) |
n |
R2 |
KT (L/g) |
B1 |
R2 |
|
0.55 |
90.9 |
0.8639 |
27.3 |
3.2 |
0.6997 |
27.6 |
9.7 |
0.8546 |
The essential characteristic of Langmuir isotherm is represented by using an equilibrium parameter, separation factor (RL), which is a dimensionless constant, according to Equation (6) (Sheela et al., 2012):
(6)
where KL is the Langmuir constant and Ci, the initial concentration of the adsorbate in the solution. This parameter is used to study Langmuir isotherm ability. Table 3 gives information about this equilibrium parameter.
Table 3. RL values and nature of the process
|
Nature of the process |
RL value |
|
Unfavorable |
|
|
Linear |
|
|
Favorable |
|
|
irreversible |
Figure 10 illustrates the values of this parameter against the initial concentration of mercury ions in the solution. Obtained values of RL are within the range of 0-1, thus Langmuir-isotherm-based adsorption is favorable.
Fig. 10. Separation factor for the adsorption of Hg (I) and Hg (II) ions onto TiO2 nanoparticles
Studying a reaction usually starts with thermodynamic studies that can predict feasibility or infeasibility of a reaction. By using thermodynamic equilibrium constant, changes in standard Gibbs free energy ( ) for adsorption at a given temperature can be determined from the following equation (Dashti Khavidaki & Aghaie, 2013; Dashti Khavidaki et al., 2013):
(7)
(8)
where T is the absolute temperature; R (kJ/molK), the gas constant; and (L/mol), the thermodynamic equilibrium constant. According to negative values of in Table 4,it is understood that adsorption process is spontaneous in experiment conditions. When the temperature rises, the tendency for adsorption decreases. Standard enthalpy and entropy ( are defined by the following equation (Arshadi et al., 2014):
(9)
Table 4. Thermodynamic parameters for the adsorption of Hg(I) and Hg (II) ions onto TiO2 nanoparticles
|
|
(kJ/mol) |
(kJ/mol) |
(J/molK) |
|||
|
T(K) |
Hg(I) |
Hg(II) |
Hg(I) |
Hg(II) |
Hg(I) |
Hg(II) |
|
295 |
-8.97 |
-10.42 |
-32.15 |
-43.81 |
-78.35 |
-113.16 |
|
308 |
-7.81 |
-8.73 |
|
|
|
|
|
318 |
-7.35 |
-7.56 |
|
|
|
|
|
328 |
-6.29 |
-6.76 |
|
|
|
|
Standard enthalpy and entropy is obtained from plot of versus (Fig. 11). The slope of this line is and its intercept, , in which and can be calculated. As shown in Table 4, according to negative values of standard enthalpy and entropy, it can be concluded that firstly, adsorption processes of both mercury (I) and mercury (II) ions onto TiO2 nanoparticles is exothermic and secondly, these adsorption processes are associated with reduced disorder.
Fig. 11. Plot of versus for the Thermodynamic parameters for the adsorption of Hg(I) and Hg (II) ions onto TiO2 nanoparticles
One of the most important studies concerning the adsorption process are known as kinetics studies, which check the effect of contact time with the adsorption percentage. Adsorption kinetics model is presented based on the reaction of the pseudo-first order by Lagergern (El-Halwany, 2010).
(10)
where (/h) is the Lagergern rate constant and and are the amounts of mercury ions adsorbed per unit mass of the adsorbent at equilibrium and time t, respectively. In these experiments, plot of versus , shown in Figure 12, is not a straight line; thus, the adsorption of mercury (I) and (II) ions onto titanium dioxide nanoparticles are not the pseudo-first order.
Fig. 12. Pseudo-first order kinetics for the adsorption of Hg(I) and Hg (II) ions onto TiO2 nanoparticles
The pseudo-second order mechanism by Ho et al. is presented (El-Halwany, 2010):
(11)
where K2 is a constant rate for pseudo-second order equation, obtained from plot of t/qt versus t (min). The slope of this straight line is and its intercept, , in which and can be calculated (Fig. 13). In accordance to the plot, the adsorption of mercury (I) and (II) ions onto titanium dioxide nanoparticles are pseudo-second order with the results, shown in Table 5.
Fig. 13. Pseudo-second order kinetics for the adsorption of Hg(I) and Hg (II) ions onto TiO2 nanoparticles
Table 5. Parameters of kinetics for Hg(I) and Hg (II) ions onto TiO2 nanoparticles
|
K2 (mg/g min) |
qe (mg/g) |
R2 |
|||
|
Hg(I) |
Hg(II) |
Hg(I) |
Hg(II) |
Hg(I) |
Hg(II) |
|
0.0053 |
0.0037 |
50.5 |
44.6 |
0.999 |
0.977 |
A few nano-adsorbents have been used to remove mercury ions from aqueous solutions. Efficiency of these adsorbents can be compared by the maximum adsorption capacity (qm), obtained from the related Langmuir isotherm. This parameter shows the maximum value of the adsorbate (mg) onto unit mass of adsorbent (g). The comparison results in Table 6 show that the highest values of qm are related to titanium dioxide nanoparticles. Therefore, in our opinion, among these nano-adsorbents, titanium dioxide nanoparticles is a more suitable adsorbent for removing mercury ions from aqueous solutions.
Table 6. Comparison of the maximum adsorption capacity for mercury ions adsorption onto a few nano-adsorbents
|
nano-adsorbents |
qe (mg/g) |
Reference |
|
multi-walled carbon nanotubes |
25.6 |
Yaghmaeian et al. (2015) |
|
magnetite-polyrhodanine core-shell nanoparticles |
36.6 |
Rahmanzadeh et al. (2016) |
|
Fe3O4@SiO2-SH nanoparticles |
90.0 |
Wang et al. (2016) |
|
titanium dioxide nanoparticles |
90.9 |
Current Work |
CONCLUSION
The results show that TiO2 nanoparticle is a good adsorbent for removing Hg (I) and Hg (II) ions from aqueous solutions. The optimum conditions for the adsorption of Hg (I) ion onto TiO2 nanoparticles are as the following: contact time= 75 min; adsorbent dosage= 0.05 g; initial concentration of Hg (I) ion= 50 mg/L; temperature= 22 °C, and pH= 9. In contrast, the optimum conditions for the adsorption of Hg (II) ion onto TiO2 nanoparticles are: contact time= 45 min; adsorbent dosage= 0.05 g; initial concentration of Hg (II) ions= 40 mg/L; temperature= 22°C, and pH= 7. Maximum adsorption of Hg (I) and Hg (II) ions onto TiO2 nanoparticles under the optimum conditions are 97.5% and 98.6%, respectively. Comparison of experimental results with adsorption isotherms of Langmuir, Freundlich and Temkin shows that adsorption of Hg (I) and Hg (II) ions by titanium dioxide nanoparticles corresponds fairly to the Langmuir adsorption isotherm model. The kinetics study of the adsorption process demonstrate that the model of kinetics for adsorption of Hg (I) and Hg (II) ions from aqueous solutions onto TiO2 nanoparticles corresponds to a pseudo-second order model.
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