Separation/Enrichment of Copper and Silver Using Titanium Dioxide Nanoparticles Coated with Poly-Thiophene and Their Analysis by Flame Atomic Absorption Spectrophotometry ()
1. Introduction
Heavy metals contamination is an important topic due to its various effects on human health and environment, and furthermore, exposure to certain heavy metals at trace amounts can entail irrecoverable and severe effects [1-4]. In addition, the presence of heavy metals in water has been a major concern for many years due to their toxicity, which endangers the aquatic-life. The sources of heavy metals pollution are mainly industries such as metal cleaning, mining activities, metal finishing, and etc [5,6].
Although copper is an indispensable element, which is needed by the human body, it can cause serious difficultties at excess amounts. Actually, water consumption with the concentration of copper at more than the permissible level of 2 mg/L [7] during years can lead to dangerous problems such as stomach and intestinal distress, liver and kidney damage, and anaemia [8]. High levels of copper may result in severe toxicity of living organisms through inhibition of metabolic reactions. The two diseases which are heavily related to copper metabolism in humans are Menkes disease and Wilson disease [9-11]. Despite its toxicity, copper plays an essential role in biological processes like blood formation and function of many important enzymes; furthermore, copper can be classified as a biogenic element due to its vital role in photosynthesis, metabolism of nitrogen compounds or regulation of RNA and DNA transcription process [12,13]. Moreover, trace levels of copper is essential as co-factors of enzymatic reactions [14].
Silver has many antimicrobial properties since ancient Romans used silver coins for treatment of drinking water; furthermore, the increased antibiotic resistance of many bacteria has led to a renewed interest in silver as a biocide agent [15]. Antimicrobial coatings of colloidal silver have various applications such as deodorizing shoe inserts, washing machines, and wound dressings [15,16]. Although silver has many applications and advantages, its high levels can be toxic to human cells. For instance, it can slow the healing of the wound. In addition, silver has other problems, including argyria which is a condition characterized by a permanent blue-gray discoloration of the skin [17]. In respect to electrical and thermal conductivity and ductility, silver has been widely used in different fields such as aerospace, communications, chemical industry, medical equipment, electroplating, photographic materials, and electronic industries. However, silver resources in the world are extremely scarce and mainly along with lead, copper and antimony deposits, and due to the low concentrations, it is necessary to preconcentrate and separate silver ions before recovery [18,19].
Analysis of trace heavy metals is difficult because of their very low concentrations in samples and high complexity of sample matrices. Therefore, preliminary preconcentration and matrix removal steps are highly needed to ensure the accuracy and precision of the analytical results [20]. Various preconcentration techniques such as solvent extraction, coprecipitation, cloud point extraction, ion-exchange, solid phase extraction and electroanalytical techniques [21-25] have been developed for various environmental samples.
Solid phase extraction (SPE) is an efficient separation-preconcentration technique for heavy metals since it has many important advantages, including simplicity, flexibility, economic, rapid, and higher enrichment factors, absence of emulsion, low cost because of lower consumption of reagents, and more importantly it is environment friendly. Various SPE materials have been successfully used for preconcentration and separation of heavy-metal ions at trace levels [26-30]. The basic principle of SPE is the transfer of the analyte from the aqueous phase to bind to active sites of the vicinal solid phase. It has several advantages over other techniques, includeing stability and reusability of the solid phase, high preconcentration factors, easy separation and enrichment under dynamic conditions, no need for consumption of organic solvents, which may be toxic and hazardous and finally, minimum costs because of low consumption of reagents [31].
Titanium dioxide nanoparticles have been widely used in commercial products such as sunscreens [32] and photocatalysts [33]; they have also been introduced as sorbents for removal of contaminants [34-36]. It is reported that TiO2 nanotubes have larger surface area compared to titanium dioxide powder itself, and contain more ion-exchangeable OH groups in the interlayer and surface [37,38]. TiO2 nanotubes has attracted great attentions in analytical chemistry because of its high chemical stability, durability, corrosion resistance, non-toxicity, and cost effectiveness. Furthermore, micro-scaled TiO2 has been used as stationary phase in HPLC applications [39] as well as a solid phase extraction adsorbent for the preconcentration of metal ions [40-42] and selective extraction of phosphates, phospholipids and phosphopeptides [43]. Moreover, TiO2 nanotubes were demonstrated to be excellent adsorbents of inorganic cations and anions as well as organic compounds [44].
In the present study, TiO2 nanoparticels were modified with poly-thiophene and used as a solid phase for simultaneous ultra-trace separation and determination of silver and copper ions in several water samples. Various factors affecting the adsorption and desorption steps for the mentioned ions were investigated and optimized. The studied factors include effects of pH, adsorption and desorption time, type, concentration, and volume of the eluent for elution of silver and copper ions, break through volume and effect of coexisting ions on separation and determination of these heavy metals. Poly-thiophene modified titanium dioxide was successfully applied for solid phase extraction of silver and copper in water samples and flame atomic absorption spectrometry (FAAS) was used to measure the above ions in solutions. Finally, the mentioned adsorbent was validated using thermogravimetry analysis (TGA), differential thermal analysis (DTA), scanning electron microscopy (SEM), Fourier transform infrared spectroscopy (FT-IR), and X-ray diffraction (XRD).
2. Materials and Methods
2.1. Reagents
TiO2 nanoparticles with 10 - 15 nm in diameter were purchased from Neutrino Company (Iran-Tehran). AIBN (2,2’-Azobisisobutyronitrile) was purchased from Acros Organics Company (New Jersey, USA). Vinyl-triethoxysilane, 3-vinyl thiophene and the other reagents used were of analytical grade and purchased from Merck Company (Darmstadt, Germany). Double-distilled water from a Milli-Q purification system (Millipore, Bedford, MA, USA) was used for the preparation of solutions. Stock solutions of Cu(II), Cd(II), Mn(II), Ni(II), Cr(III), Al(III), Fe(II), Pb(II), Mg(II), Ca(II), Cs(I), Na(I), Ag(I), and K(I) were prepared from Titrisol solutions (Merck, Darmstadt, Germany). Working solutions were prepared by dilution of stock solutions (1000 mg∙L−1) with deionized water. HCl, HNO3, and CH3COOH as the elution solvents were purchased from Merck Company (Whitehouse Station, NJ, USA).
2.2. Instrumentation
Copper and silver concentration was determined by an AA-680 Shimadzu (Kyoto, Japan) flame atomic absorption spectrometer (FAAS) in an air–acetylene flame, according to the user’s manual, provided by the manufacturer. Copper and silver hollow cathode lamps (HCL) were used as the radiation source with wavelengths of 324.8 and 328.1 nm, respectively. All pH measurements were recorded at 25˚C ± 1˚C with a digital WTW Metrohm 827 Ion Analyzer (Herisau, Switzerland), equipped with a combined glass-calomel electrode. X-ray diffraction patterns were obtained on a STOE diffractometer with Cu Ka radiation. The Elemental analysis was performed with a Thermo Finnigan Flash-2000 microanalyzer (Italy). IR spectra were recorded by BOMEM/MB series Spectrometer. Thermal gravimetric and differential thermal analysis (TG/DTA) was carried out on a Bahr STA-503 instrument under air atmosphere. SEM micrograph was recorded on Vega-TeScan microscope.
2.3. Synthesis of Vinyl Functionalized TiO2 Nanoparticles
For synthesis of vinyl functionalized TiO2 nano-particles, 1.0 g of TiO2 nanoparticles was suspended in 50 mL of toluene, afterward 2 mL of vinyl-triethoxysilane was added to the solution, and the mixture was stirred at room temperature for 48 h. The white solid was separated by filtration, washed with ethanol and dried at room temperature. The vinyl functionalization was confirmed by IR spectroscopy and elemental analysis. Elemental analysis of this nanocomposite shows that the vinyl concentration is approximately 0.74 mmol per gram of TiO2 nanoparticles (C = 2.66%, H = 0.38%).
2.4. Preparation of Poly-Thiophene Coated TiO2 Nanoparticles
The coating of polymer on the surface of TiO2 nanoparticles was carried out by simple polymerization of vinyl groups on the surface of TiO2 nanoparticles and 3-vinyl thiophene. In this approach, 0.1 g vinyl-TiO2 nanoparticles was suspended in 100 mL of methanol containing 100 μL of 3-vinyl thiophene and then 0.2 g of AIBN was added to the mixture and was heated to 60˚C. After 24 h the composite was separated by centrifuge, washed with methanol and dried in the vacuum at 80˚C. The formation of poly-thiophene on the surface of TiO2 nanoparticle was confirmed by IR spectroscopy, X-ray powder diffraction, elemental, and thermal analysis. A schematic diagram for synthesis of this composite is shown in Figure 1.
2.5. Real Samples Pretreatment
Standard materials with a certified amount of copper and silver ions were used for method validation. These samples were digested in an 8 mL mixture of 5% aqua regia with the assistance of a microwave digestion system. Digestion was carried out for 2 min at 250 W, 2 min at 0 W, 6 min at 250 W, 5 min at 400 W and 8 min at 550 W, and the mixture was then vented for 8 min. The residue from this digestion was then diluted with deionized water.
The water samples, including distilled water, tap water (Tehran, Iran), river waters obtained from Siahrood river and Derka river (Ghaemshahr, Iran) and sea water (Caspian Sea, Sari, Iran) were collected in cleaned polyethylene bottles and filtered through a 0.45 mm pore size nylon filter (Millipore) immediately after sampling. The amounts of copper and silver ions were then successfully determined by the present method.
3. Results and Discussion
3.1. Sorbent Characterization
The polymerization reaction of vinyl functionalized TiO2 nanoparticles with 3-vinyl thiophene in presence of AIBN as the initiator leads to formation of this sorbent. A schematic diagram for synthesis of this composite is shown in Figure 1. The formation of poly-thiophene on the surface of TiO2 nanoparticles was confirmed by IR spectroscopy, X-ray powder diffraction, elemental and Thermal analysis. The presence of peaks at 3038 (CH, aromatic), 2979 (CH, aliphatic), 1559 (C = C, aromatic) in IR spectrum confirm the presence of thiophene in this sorbent. The amount of grafted pyridine was calculated by elemental analysis. According to the elemental analysis results, approximately 1.88 mmol thiophene is grafted on each gram of TiO2 nanoparticles. In order to confirm TiO2 nanoparticles remain intact after functionalization (no decomposition), XRD pattern of final product was recorded. Comparing to the reference pattern (JCPDS file, No. 86-0147) the results show that the structure of TiO2 nanoparticles remained intact after coating with the polymer (Figure 2). In order to investigate the size and morphology of sorbent, SEM micrograph of the sorbent was recorded. As it can be seen in Figure 3, spherical nanoparticles with approximately 40 - 60 nm in diameter were obtained. Finally, the thermal stability of this sorbent was investigated by TG-DTA analysis. According to these results, this sorbent is stable up to 270˚C (Figure 4). Furthermore, according to these results, approximately 24% of this material is consisting of poly-thiophene polymer.
3.2. Sorption Step
3.2.1. Effect of Solution’s pH
Among the tested variables, pH was found to be the most critical parameter for adsorption of metals on the polythiophene-TiO2 nanoparticles [45]. To evaluate the effect of pH on the extraction efficiency, the pH of 25 mL of sample solutions containing 2 mg·L−1 of copper and silver ions was adjusted in the range of 2 to 9. The data graphed as a function of pH for poly-thiophene-TiO2 nanoparticles is shown in Figure 5. As can be seen in Figure 5, the quantitative retention of copper and silver ions on the poly-thiophene-TiO2 nanoparticles was obtained in the pH of 7. Thus, all samples were adjusted to pH 7 for further studies.
3.2.2. Equilibrium Sorption Time
In a typical uptake kinetics test, 15 mg of the sorbent was added to 25 mL of 2 mg·L−1 Cu(II) and Ag(I) aqueous solution at pH 7. The resulting suspension was stirred in different times (i.e., from 2 to 10 min) under magnetic stirring. According to the results in Table 1, an optimum
Figure 1. Schematic illustration of poly-thiophene coated TiO2 nanoparticles.
Figure 2. XRD pattern of poly-thiophene coated TiO2 nanoparticles.
Table 1. Influence of sorption and desorption Times on retention and recovery of copper and silver poly-thiophene coated TiO2 nanoparticles.
Figure 3. SEM micrograph of poly-thiophene coated TiO2 nanoparticles.
Figure 4. TGA and DTA poly-thiophene coated TiO2 nanoparticles.
Figure 5. Effect of sample pH on the retention of Cu(II) and Ag(I) ions on poly-thiophene coated TiO2 nanoparticles.
equilibration time of 7 min was obtained for quantitative extraction of the analytes from solution into the solid phase.
3.2.3. Effect of Amount of Nanoparticles
The influence of the mass of nanoparticles (5 - 20 mg) used for quantitative extraction of copper and silver was investigated. 15 mg of the nanoparticles was obtained as the optimum amount of adsorbent. Subsequent experiments were performed for 15 mg modified nanoparticles.
3.3. Desorption Step
3.3.1. Effect of Type, Concentration and Volume of Eluent
Various solvents such as HNO3, HCl, and acetic acid were tested to obtain the best eluent for the removal of Cu(II) and Ag(I) ions [46]. According to experiments, HCl showed the best recovery among other solvents. The effects of eluent’s concentration and volume on the recovery of copper and silver ions were also studied. As shown in Table 2, best quantitative recovery can be obtained with 5 mL of HCl (2 mol·L−1). After the sorption of Cu(II) and Ag(I) ions by the nanoparticles, the nanoparticles were separated from the solution through filtration. Then, poly-thiophene-TiO2 nanoparticles were first washed with distilled water in order to remove nonspecifically retained matrices from the nanoparticles. Then, modified TiO2 nanoparticles were dried, and the extracted copper and silver ions were eluted by HCl through batch experiments.
3.3.2. Desorption Time
In order to investigate the optimum desorption time, various times were examined in the range of 2 to 15 min, while other parameters were kept in optimum conditions. As shown in Table 1, extraction recovery was increased up to 10 min and it was constant in longer times. Therefore, 10 minutes can be the best quantitative time for the elution of metal ions from the poly-thiophene-TiO2 nanoparticles.
3.4. Effect of Sample Volume
In the analysis of real samples, the sample volume is one of the important parameters influencing the preconcentration factor. Therefore, the effect of sample volume on quantitative adsorption of Cu(II) and Ag(I) ions was investigated. For this purpose, 15 mg of nanoparticles was suspended in different sample volumes (25, 50, 100, 250, 500, 750, 900, 1000, 1250, 1400 and 1500 mL), and the total amount of loaded Cu(II) and Ag(I) was kept constant in 0.1 mg. All solutions were extracted under the optimum conditions by the proposed method. The results in Figure 6 demonstrated that the simultaneous quantitative recovery of copper and silver ions on poly-thiophene-TiO2 nanoparticles can be obtained for sample volume up to 900 mL.
3.5. Evaluation of Adsorption Capacity
In this work, Langmuir isotherms were used to measure the adsorption of copper and silver ions onto poly-thiophene-TiO2 surface. The Langmuir adsorption model is a theoretical equation and applicable to homogeneous binding sites and assumes that the molecules are adsorbed at a fixed number of well-defined sites, each of which can only hold one molecule. These sites are also assumed to
Table 2. The effect of type, concentration, and volume of the eluent on extraction efficiency.
aRecovery; bStandard deviation.
Figure 6. Effect of sample solution volume on extraction recovery of copper and silver ions on poly-thiophene coated TiO2 nanoparticles.
be energetically equivalent and distant to each other; therefore, there are no interactions between molecules adsorbed on adjacent sites. The amount of Cu(II) and Ag(I) bound by the nanoparticles was calculated according to the following formula:
where Q is the amount of adsorbed Cu(II) and Ag(I) (mg∙g−1); C0 and C are the initial and final concentrations of Cu(II) and Ag(I) (mg∙L−1), respectively; V is the volume of mixture (mL); and W is the amount of nanoparticles (g).
The Langmuir adsorption isotherm is expressed by Equation (6).
where Q is the amount of adsorbed Cu(II) and Ag(I) ions on the poly-thiophene-TiO2 nanoparticles at equilibrium (mg∙g−1), Ce is the equilibrium concentration of Cu(II) and Ag(I) ions in solution (mg∙L−1) and Qmax and b are Langmuir constants related to the maximum adsorption capacity and energy of adsorption, respectively. The Langmuir equation can be linearized in a normal form for the determination of Langmuir constants:
Langmuir equations for copper and silver at pH 7 for 25 mL of sample volume and 15 mg of the sorbent are as follows:
Y = 0.123 X + 0.024 (R2 = 0.996) Langmuir equations for copper;
Y = 0.158 X + 0.032 (R2 = 0.995) Langmuir equations for silver.
According to the relations above, adsorption capacities for Cu(II) and Ag(I) were calculated to be 41.66 mg∙g−1 and 31.25 mg∙g−1, respectively.
3.6. Effect of Interfering Ions
In order to investigate the effect of various cations existed in natural samples; elements that are known as alkaline, alkaline earth, and transition metals were added to 100 mL of solution containing 0.01 mg copper and silver ions. The degree of tolerance for some alkaline, alkaline earth and transition metal ions is presented in Table 3. From the tolerance data, it can be found that the other ions have no significant effects on preconcentration of copper and silver ions at pH of 7.0.
3.7. Statistical and Calibration Parameters
Under optimum conditions that have been described, this SPE method showed a linear calibration curve within concentration ranging from 1 to 100 µg∙L−1 for copper and 3 to 120 µg∙L−1 for silver. The least square equation at above dynamic linear range for copper and silver was as follows:
The limits of detection, defined as CLOD = 3Sb/m, where Sb is the standard deviation of 6 replicate blank
Table 3. The tolerance limit of various ions on the determination of copper and silver ions.
aRecovery; bStandard deviation.
signals and m is the slope of the linear section of the calibration curve after preconcentration, for a sample volume of 500 mL, was found to be 0.4 ng∙mL−1 for copper and 1.2 ng∙mL−1 for silver ions. In order to calculate the blank value, 15 mg of the modified nanoparticles was added to 500 mL of blank solution and the solution was stirred for 7 min. Then, the solution was filtered and the remaining nanoparticles was added to 5 mL of HCl (2 mol∙L−1) as the elution solvent and, again the solution was stirred for 10 min. Finally, the solution was filtered and determined by FAAS. The relative standard deviation for six separate batch experiments with 15 mg of sorbent for determination of 8 µg of Cu(II) and Ag(I) in 500 mL of water was 3.1% and 2.2%, respectively.
3.8. Real Sample and Certified Reference Material Analysis
The applicability of the sorbent for preconcentration and determination of trace levels of Cu(II) and Ag(I) was tested using different water samples. For the preconcentration procedure, pH of 500 mL of real samples was adjusted to 7.0 and spiked with copper and silver ions and was used in batch method. The concentration of sorbed Cu(II) and Ag(I) ions were determined based on a triplicate analysis (Table 4). It was found that the quantitative extraction of copper and silver ions was performed successfully by the sorbent even in the presence of various diverse ions.
Certified reference material (ore polymetallic gold zidarovo-PMZrZ (206 BG 326)) was used for the validation of the proposed method. As it can be seen in Table 4, good correlation was achieved between estimated content by the present method and reference materials. Therefore, poly-thiophene-TiO2 nanotubes can be used as a reliable solid-phase for extraction and determination of copper and silver ions in water samples.
4. Conclusion
In this study, a simple, efficient and reliable method was set up to determine the trace amounts of copper and silver in the aqueous solution using modified titanium oxide nanoparticles as SPE sorbent coupled with FAAS. According to our experimental results, TiO2 nanoparticles modified with poly-thiophene have good analytical potential for the extraction of silver and copper ions from real environmental water samples. Taking into account the simplicity and low cost of poly-thiophene-TiO2 nanoparticles, as well as the good extraction efficiencies, these modified nanoparticles have a great potential of becoming a cost effective and useful extraction tool in analytical methods. The precision and accuracy of the proposed method were satisfactory and percentage of Ag(I) and Cu(II) removal from solution is close to 100% at pH of 7.
Table 4. The determination of copper and silver in various real samples and certified reference material.
5. Acknowledgements
We gratefully acknowledge financial support from the Research Council of Shahid Beheshti University.
NOTES