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Adsorption of Ag(Ⅰ) on H2TiO3 from aqueous solutions
CHAI Li-yuan(柴立元)1, WEI Shun-wen(韦顺文)1, PENG Bing(彭 兵)1, LI Zhu-ying(李竹英)2
1. School of Metallurgical Science and Engineering, Central South University, Changsha 410083, China;
2. Yiwu Bureau of Quality and Technical Supervision, Yiwu 322000, China
Received 23 June 2006; accepted 17 May 2007
Abstract: Adsorption of silver ions from aqueous solution onto H2TiO3 was studied. Equilibrium experimental studies were performed to determine the adsorption capacity of H2TiO3 for silver ion at various pH values. Batch experiments were conducted in the range of pH value 3-7 and silver ions concentration 10-200 mg/L. The results show that the adsorption is strongly dependent on pH value. The equilibrium absorption capacity of H2TiO3 increases significantly with the increase of pH value from 3 to 7. The adsorption of silver ion obeys the Langmuir isothermal equation well in the concentration range studied, the adsorption constant is 0.054 7, 0.052 4, 0.088 1 at pH 5, 6 and 7, respectively, and the maximum adsorption capacities are 23.64, 29.76 and 40.82 mg/g.
Key words: silver ions; adsorption; hydrous titania
1 Introduction
Titania is well known as an attractive photocatalyst. However, the photocatalytic activity of titania is not strong enough in practical application so that the modification of titania with metal ions[1-4] such as Fe, Au, Ag and Sn to improve its photocatalytic efficiency has been investigated by many researchers. It is widely known that titania containing various inorganic substances such as silver, copper and zinc, shows antibacterial property[5-7], Ionic silver has the highest antibacterial activity among metal ions[8-10]. Recently, silver-doped titania antibacterial materials have been developed and some of them are in commercial use.
There are several techniques to make silver-doped materials (e.g. sol-gel method, high-temperature glass fusion, ion implantation, ion exchange, sputtering, etc.). Especially, the ion exchange method has several advantages such as uniform distribution, low processing temperatures, perfect antibacterial activity, and it is possible to get rid of reduction of silver ions with a high mass fraction. Therefore, many efforts have been paid for the preparation of silver-containing materials by the ion exchange method. FENG et al[11] prepared Ag/HAp by the ion exchange between Ag+ and Ca2+ in Hap and studied the morphology and structure of Ag/HAp by SEM and XRD. AYBEN and ULKU[12] studied the ions exchanges activity of Ag+, Zn2+, and Cu2+ in a Na-clinoptilolite and the effect of preparing parameters on antibacterial properties. PARK and JANG[13] prepared Ag/ACF and investigated the adsorption behavior and antibacterial activity of ACF supported with silver (Ag/ACF). But for the preparation of silver-doped titania antibacterial materials, there were very few reports in the survey of the adsorption behavior on H2TiO3. In this paper, we investigated the adsorption behavior of silver ions on H2TiO3.
2 Experimental
2.1 Materials
The H2TiO3 was prepared by forced-hydrolysis of titanium sulfate (Ti4+: 0.375 mol/L, H+: 3 mol/L) in autoclave at 125 ℃ for 2 h. The H2TiO3 was used without any heat or chemical treatment for adsorption studies. The size of H2TiO3 was measured by particle size analyzer (MS-2000). The average size of the particles is 0.2 μm, and its specific surface is 13.8 m2/g. The stock solution of Ag+ (1 g/L) was prepared by dissolving 0.157 4 g of AgNO3 into 10 mL HNO3 (0.01 mol/L) and making the volume to 1 L with distilled water. All working solutions were prepared by diluting the stock solution with distilled water.
2.2 Methods
2.2.1 Dynamic adsorption
Before conducting the equilibrium adsorption experiments, the dynamic adsorption experiments were conducted to determine the time required to reach equilibrium. The dynamic adsorption measurements were carried out at room temperature ((25±1) ℃) on a rotary shaker using 500 mL capped conical flask. 0.2 g of H2TiO3 was mixed into 200 mL of silver containing solution of known concentration. Solution was taken at various periods of time and analyzed for silver ions concentration(ct). The adsorption density q (mg/g) at different time was calculated by the equation:
q=(cs-ct)V/M (1)
where cs is the initial concentrations of silver ions in the solution (mg/L), V is the volume of the solution (L), M is the amount of the H2TiO3 used (g).
2.2.2 Equilibrium adsorption
Five solutions of pH (3, 4, 5, 6 and 7) were prepared by adding appropriate volumes of 0.1 mol/L HNO3 or 0.1 mol/L NaOH solution of distilled water. The pH of solution was measured using microprocessor pH meter model H18417 by Hunan instruments. The shaking experiment was carried out in a thermostat shaker bath. Adsorption measurements were carried out in a batch technique at room temperature (25±1) ℃, 200 mL of silver containing solution of known concentration were shaken with H2TiO3 (0.2-1.0 g) in 500 mL reagent glass bottle for 2h. The solution was filtered through filter paper and analyzed for silver ions concentration.
The equilibrium adsorption density qe (mg/g) was computed using the following equation:
qe=(cs-ce)V/m (2)
where cs and ce stand for the initial and final concentrations of silver ions in the solution (mg/L), respectively, V stands for the volume of the solution (L), m stands for the amount of the H2TiO3 used (g).
2.2.3 Analysis method
The solution was filtered through filter paper; the first 5 mL portion of the filtrate was rejected because of the adsorption of silver ions on filter paper. The concentration of silver ions in measuring filtrate was determined with Atomic Absorption Spectrophotometer (AAS 200A Buck Scientific Model) and corrected for losses due to adsorption on the walls of the glass bottles by running blank experiments (without H2TiO3 added).
3 Results and discussion
3.1 Dynamics of Ag+ absorbed
The results (Fig.1) showed that the absorption equilibrium was quickly reached with an initial concentration cs of silver ion 50 mg/L in 5 min. For higher values of cs reached, the equilibrium took about 10 min. After 10 min of the suspension skating, more than 20% of Ag+ (cs=200 mg/L) was already adsorbed from the aqueous solution, about 50% of Ag+ was adsorbed from the aqueous solution with the smaller value of cs (50 mg/L). To ensure equilibrium was attained, we choose contact time equal to 2 h to undertake the following experiments.
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Fig.1 Dynamics of Ag+ absorbed by H2TiO3 (pH=7, t=25 ℃)
3.2 Effect of pH
According to surface complexation theory, the reactive surface sites of hydrated metal oxides are comprised of metal-hydroxyl sites that can react with ions in solution. The surface acidity of these sites on H2TiO3 surface can be described as[14]
![](/web/fileinfo/upload/magazine/83/2821/image006.gif)
TiOH0+H+;
(3)
TiOH0
TiO-+H+;
(4)
where
, TiOH0 and TiO- represent the protonated, neutral and ionized surface hydroxyl groups, respectively,
and
the respective acidity constants.
Surface acidity is an important property of hydrous titania (H2TiO3) which relates to the extent of interfacial reactions including adsorption of metal ions. Since the surface charge of an adsorbent can be modified by changing pH of the solution, pH is one of the most important parameters affecting the adsorption process of silver ions. Therefore, the effect of pH on the silver ions adsorption was investigated in the pH range of 3-7 using 0.2 g of H2TiO3 at the concentration of silver ions as 20, 30 and 40 mg/L, respectively. The variation of equilibrium adsorption density(qe) with rise in pH of the solution is shown in Fig.2. It is obvious from this figure that the qe value for sliver ions adsorption on H2TiO3 increases with increasing pH from 3 to 7, and it increases very sharply at pH above 5. With an initial concentration (cs) 20 mg/L of silver ion, the qe value increases from 8.2 mg/g to 9.4 mg/g as pH increases from 3 to 5. While the pH value increases up to 7, the qe value attains 15.3 mg/g. The qe value also increases with increasing silver ions concentration at the same pH value, but the extent of qe increase is different at the various pH values.
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Fig.2 Effect of pH on adsorption
The influence of pH on silver ions adsorption can be explained as follows: low adsorption of silver ions on H2TiO3 at low pH is due to strong H+ ion competition for the available exchange sites or a surface adsorption phenomenon in which the adsorbent surface does not favor the adsorption of positively charged ions at low pH.
3.3 Effect of silver ions concentration
The adsorption of silver ions on the H2TiO3 was studied as a function of initial concentration of silver ions in the range of 10-150 mg/L while keeping all other parameters constant, and the results are shown in Fig.3 and Fig.4. The equilibrium concentration of silver ions(ce) obtained was plotted against initial concentration of silver ions(cs) at various pH values in Fig.3. The adsorption density values obtained were plotted versus equilibrium concentration of silver ions in Fig.4.
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Fig.3 Curves of equilibrium concentration of silver ions(ce) vs initial concentration of silver ions(cs) at various pH values
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Fig.4 Curves of equilibrium concentration of silver ions (ce) in bulk solution vs its adsorption density (qe)at various pH values
It is obvious that the increase of the initial concentration in silver ion gives a substantial increase in the quantity of retained silver ion in bulk solution for the same quantity of H2TiO3 (Fig.3). The increase in initial concentration of silver ion for the same mass of H2TiO3 creates a great increase of molecules of silver ion adsorbed on the free sites of the surfaces of particles H2TiO3, the equilibrium adsorption density (qe) increases quickly with increasing equilibrium concentration of silver ions between 0.05 and 20 mg/L, especially at pH=7 (Fig.4). When the equilibrium concentration of silver ions is higher than 20 mg/L, most of sites are occupied, more and more silver ion remain in the liquid phase and equilibrium adsorption density (qe) approaches to its maximum limit qm.
3.4 Effect of adsorbent dosage
The effect of adsorbent dosage on the adsorption of silver ions was studied by varying the amount of H2TiO3 from 0.2 to 1.0g in 200 mL solutions (cs=50 mg/L) at pH=7 and 2h of contact time. The adsorption percent values ((cs-ce)/cs)×100% obtained are plotted versus adsorbent dosage in Fig.5.
![](/web/fileinfo/upload/magazine/83/2821/image021.jpg)
Fig.5 Effect of adsorbent dosage on adsorption of silver ions
It can be seen from Fig.5 that the amount of silver ions adsorption increases quickly with increasing adsorbent dosage. This is an expected result that as the amount of the adsorbent increases, the number of adsorbent particles surrounded by silver ions or the ratio of the number of adsorbent particles to that of silver ions increases in the solutions, resulting in thus more ions adsorbed onto the adsorbent surfaces.
3.5 Adsorption models
The Langmuir adsorption isotherm[15] is one of the most widely used models for describing of the adsorption of a solute from a liquid solution and it has been successfully applied in many studies on adsorption of various metal ions. A basic assumption of the Langmuir law is that the adsorption takes place on specific homogeneous sites of the adsorbent surface. It is then assumed that once a metal ion occupies a site, no further adsorption can take place at that site. The rate of adsorption to the surface should be proportional to a driving force per unit area. The driving force is the concentration in the solution, and the area is the amount of bare surface. The saturated monolayer isotherm can be represented as
(5)
The above equation can be rearranged to the following linear form:
(6)
where ce is the equilibrium concentration in bulk solution (mg/L); qe is the amount of metal ion absorbed (mg/g); qm is the maximum adsorption capacity (mg/g); k is the adsorption equilibrium constant (L/mg). A plot of ce/qe versus ce should indicate a straight line of slope 1/qm and an intercept of 1/(kqm). The straight line was obtained by plotting ce/qe against ce. Fig.6 indicates the conformity of the data to the Langmuir equation as well. Values of constants qm and k were calculated from the slope and intercept. The calculated results of the adsorption constant k and the specific maximal quantity qm are shown in Table 1.
![](/web/fileinfo/upload/magazine/83/2821/image027.jpg)
Fig.6 Langmuir isotherm plots for adsorption of silver ions on H2TiO3 at various pH values
Table 1 Constants of Langmuir isotherm at various pH values
![](/web/fileinfo/upload/magazine/83/2821/image028.jpg)
It can be seen from Table 1 that the specific maximal quantity qm increases with increasing pH, the adsorption constant k is almost the same at pH=5 and pH=6, but it has a high value at pH 7.
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Foundation item: Project(04GK2007) supported by the Key Project of Scientific and Technological Department of Hunan Province, China
Corresponding author: CHAI Li-yuan; Tel: +86-731-8836840, Fax: +86-731-8710171; E-mail: lychai@mail.csu.edu.cn
(Edited by HE Xue-feng)