Preparation, Characterization, and Application of Magnetic Fe-SBA-15 Mesoporous Silica Molecular Sieves

Huang, Huayu; Ji, Yongsheng; Qiao, Zhenfeng; Zhao, Chuande; He, Jianguo; Zhang, Haixia

doi:https://doi.org/10.1155/2010/323509

Journal of Analytical Methods in Chemistry

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Abstract Introduction Materials and Methods Results and Discussion Conclusions Acknowledgments References Copyright Related Articles

Research Article | Open Access

Volume 2010 | Article ID 323509 | https://doi.org/10.1155/2010/323509

Preparation, Characterization, and Application of Magnetic Fe-SBA-15 Mesoporous Silica Molecular Sieves

Huayu Huang,^1,2Yongsheng Ji,¹Zhenfeng Qiao,¹Chuande Zhao,¹Jianguo He,¹and Haixia Zhang¹

Academic Editor: Xiu-Ping Yan

Received24 Mar 2010

Accepted19 Jul 2010

Published05 Dec 2010

Abstract

Magnetic Fe-SBA-15 mesoporous silica molecular sieves were prepared, characterized, and used for magnetic separation. Wet impregnation, drying, and calcination steps led to iron inclusion within the mesopores. Iron oxide was reduced to the metal form with hydrogen, and the magnetic Fe-SBA-15 was obtained. Fourier-transform infrared spectroscopy confirmed the preparation process from the oxide to metal forms. The structure of magnetic materials was confirmed by Mössbauer spectra. Powder X-ray diffraction data indicated that the structure of Fe-SBA-15 retained the host SBA-15 structure. Brunauer-Emmett-Teller analysis revealed a decrease in surface area and pore size, indicating Fe-SBA-15 coating on the inner surfaces. Scanning electron micrographs confirmed the decrease in size for modified SBA-15 particles. From scanning electron micrographs, it was found that the size of the modified SBA-15 particles decreased. Transmission electron micrographs also confirmed that modified SBA-15 retained the structure of the parent SBA-15 silica. Fe-SBA-15 exhibited strong magnetic properties, with a magnetization value of 8.8 emu g^-1. The iron content in Fe-SBA-15 was determined by atom adsorption spectroscopy. Fe-SBA-15 was successfully used for the magnetic separation of three aromatic compounds in water. Our results suggest wide applicability of Fe-SBA-15 magnetic materials for the rapid and efficient separation of various compounds.

1. Introduction

Mesoporous SBA-15 silica molecular sieves of large pore diameter (up to 30 nm) and area (up to 1000 m² g^-1) [1] show excellent homogeneity and stability and can be well controlled for adsorption/desorption processes [2]. Mesoporous silica materials, especially mesoporous SBA-15 molecular sieves, have been modified with 3-mercaptopropyl, 3-aminopropyl, octyl, or octadecyl groups for the separation and analysis of inorganic ions, organic compounds, and biological molecules [2–5]. However, SBA-15 is notoriously difficult to separate from solution. Magnetic separation is a useful tool because of its fast recovery, high efficiency, and low high cost [6]. Inclusion of magnetic components in modified materials allows convenient and economical magnetic separation instead of centrifugation and filtration steps on application of an appropriate magnetic field [7–9]. Because of their potential applications in this approach, the preparation of Co, Co/Fe, α-Fe₂O₃, γ-Fe₂O₃, and Fe₃O₄ magnetic SBA-15 materials have been reported [10–15].

We propose a convenient and effective procedure for iron doping of mesoporous SBA-15 silica because of its excellent magnetic properties. The product was prepared by wet impregnation, calcinations, and reduction. First, the pores of SBA-15 were doped with iron ions. Then Fe³⁺ was transformed to the oxide form by calcination in the air. Finally, ferric oxide in SBA-15 was reduced with H₂ [7, 15, 16]. Figure 1 shows a flow diagram for preparation of magnetic SBA-15. Fourier-transform infrared (FT-IR) spectroscopy, powder X-ray diffraction (XRD), Mössbauer spectra (MS), surface area analysis, scanning electron microscopy (SEM), and transmission electron microscopy (TEM) techniques were used to characterize the material. The magnetic behavior was determined using a vibrating sample magnetometer. The iron content in Fe-SBA-15 was determined by atom adsorption spectroscopy (AAS).

With the development of petroleum refining and chemical engineering, the release of harmful organic chemicals into the environment has attracted global attention because of their toxicity and widespread use, especially aromatic compounds considered as carcinogenic [7]. The aim of the present study was to develop a method for preparing magnetic SBA-15 for use as a sorbent to remove benzene and related derivatives from water. The adsorption of benzene, toluene, and ethyl benzene on magnetic SBA-15 particles was determined by gas chromatography (GC).

2. Materials and Methods

2.1. Materials

Mesoporous SBA-15 silica molecular sieves were purchased from Changchun Jilin University High-Tech. Co. Ltd. (Jilin, China). Fe(NO₃)₃ was purchased from Tianjin Chemical Reagent Co. Ltd. (Tianjin, China). Benzene, toluene, and ethyl benzene were purchased from Sigma (St. Louis, MO, USA). Deionized water was prepared using a Millipore unit (Bedford, MA, USA).

2.2. Sample Preparation

SBA-15 was soaked in 0.1 mol L^-1 HCl for 24 h, filtered, washed with deionized water, and dried in an oven at 100°C for 8 h.

A sample of 2 g of SBA-15 was dispersed in 1 mol L^-1 Fe(NO₃)₃ solution by ultrasonication for 2 h. The material was filtered under low pressure and dried in an oven at 100°C. Samples were calcined in a muffle furnace at 750°C for 6 h to obtain a red powder, which was then reduced under a H₂ flow (35 mL min^-1) at 800°C for 6 h. The final product was designated Fe-SBA-15.

2.3. Characterization

FT-IR spectra of SBA-15 particles were recorded before and after modification on a Nicolet (USA) 360 FT-IR instrument.

Powder XRD patterns were measured on a D/max-2400 (Rigaku, Japan) instrument using Cu K_α radiation.

Fe Mössbauer spectra were collected using a conventional constant acceleration spectrometer (Wissel, German) with a 25 m Ci source of ⁵⁷Co in palladium at room temperature. The percentage of Fe, Fe(II), and Fe(III) were calculated and contributor of magnetic behavior was confirmed.

Nitrogen adsorption-desorption experiments were carried out at 76.53 K on an ASAP 2010 accelerated surface area and porosimetry system (Micromeritics, USA). The Brunauer-Emmett-Teller (BET) surface area () was calculated from the linearity of the BET equation. The surface area, volume and pore diameter were calculated from pore size distribution curves using the Barrett-Joyner-Halenda (BJH) formula.

The surface morphology of powders was observed under a JSM-6380LV scanning electron microscope (Jeol, Japan).

For TEM observation, samples were dispersed in ethanol, deposited on a grid of holey copper and transferred to a JEM-1230 emission electron microscope (Jeol, Japan) at an accelerating voltage of 100 kV.

A Lakeshore (USA) 7304 vibrating sample magnetometer was used to record magnetization curves of the samples.

2.4. Determination of Iron in Fe-SBA-15

A sample of 10 mg of Fe-SBA-15 was heated in a mixture of hydrochloric acid and nitric acid to completely dissolve the iron and transferred to a 25-mL volumetric flask and made up to volume with water. The solution was centrifuged at 10000 rpm and the iron concentration was determined on an AA-6800 instrument (Shimadzu, Japan). Standard Fe³⁺ solutions (0, 2.0, 4.0, 8.0, 10.0 μg mL^-1) were measured to generate a standard curve.

2.5. Adsorption of Aromatic Compounds

Benzene, toluene, and ethyl benzene, were dissolved in deionized water at a concentration of 1.0 ppm each. Then 20 mg of Fe-SBA-15 was added to the aqueous solution and sonicated at room temperature (approx. 20°C) for 30 s to form a homogeneous dispersion. After standing for 5 min, Fe-SBA-15 was collected from the dispersion using a magnet and the supernatant was discarded. The absorbed model compounds were eluted in 0.5 mL of methanol. Finally, 1.0 μL of the eluate was analyzed on a Varian (USA) CP-3380 gas chromatograph and the content of the aromatic compounds was calculated.

3. Results and Discussion

3.1. FT-IR

Figure 2 shows FT-IR spectra of Fe(NO₃)₃, SBA-15, Fe(NO₃)₃-SBA-15, Fe₂O₃-SBA-15, and Fe-SBA-15. The IR vibration for the ion at 1385 cm^-1 is evident in curves a and c, but not in b, indicating that Fe(NO₃)₃-SBA-15 was prepared successfully. Fe₂O₃-SBA-15 was obtained by transformation from the nitrate to the oxide form, as confirmed by the disappearance of the peak at 1385 cm^-1 after calcination (curve d) [16]. The peak at 1385 cm^-1 also disappeared after Fe₂O₃-SBA-15 reduction (curve e). The material was red after Fe(NO₃)₃-SBA-15 calcination at 750°C, suggesting that iron oxide is mainly in the form of α-Fe₂O₃ (hematite). Hematite is extremely stable under ambient conditions and is often the end product of the transformation of other iron oxides [17].

3.2. XRD and MS

XRD patterns of the materials are shown in Figure 3. In the narrow-angle range peaks for SBA-15 are evident at 0.8°, 1.4° and 1.7°. For Fe-SBA-15, there is one prominent peak at 0.9° and two peaks at 1.5° and 1.8°. These results indicate that magnetic Fe-SBA-15 still has a high degree of hexagonal symmetry [1, 19] and retains the structure of SBA-15 after calcination at 750°C and reduction at 800°C, indicating that SBA-15 has good hydrothermal stability. Peaks for iron are evident at 44.6° and 65° in the wide-angle XRD pattern for Fe-SBA-15 [20, 21]. Other peaks can be attributed to Fe₂O₃, Fe₃O₄ or FeO [20–24]. Residual iron oxides may be a result of surface passivation [20], which can be explained by the following equations for reduction of Fe₂O₃ with hydrogen [25]:

(a)

(b)

(c)

Figure 4 shows Mössbauer spectra of Fe-SBA-15 and Table 1 shows Mössbauer parameters of Fe-SBA-15. From the calculation of Fe Mössbauer spectra, the percentage of Fe, Fe(II), and Fe(III) in the prepared materials were 17.0%, 64.5%, and 18.5%, respectively. The above results could also confirm that the reduction process followed the equations and the reduction was not complete under this condition. Furthermore, it can be seen that the magnetic behavior of Fe-SBA-15 was contributed by Fe₃O₄.

3.3. Nitrogen Adsorption-Desorption Measurements

Figure 5 shows nitrogen adsorption-desorption isotherms for the materials, which exhibit a typical type IV isotherm with an H1 hysteresis loop as defined by IUPAC [26]. The H1 hysteresis loop indicates that Fe-SBA-15 was still a mesoporous material. However, there was a shift in hysteresis position to lower relative pressure and a decreasing trend. The shift of the sharp inflection from 0.60 to 0.80 is characteristic of a diameter in the mesopore range [27, 28]. Pore parameters for the materials are shown in Table 2. The BET surface area changed from 524 to 308 m² g^-1 and the pore diameter decreased from 72.8 to 72.6 Å on modification of SBA-15 with Fe. The decrease in surface area and pore diameter, probably caused by filling of the pores with small iron particles, indicates successful iron doping within the mesoporous channels of SBA-15 [29]. The pore diameter and data for the two materials indicate that the mesopore uniformity of the parent SBA-15 silica was retained in the modified material [27].

3.4. SEM

SEM images of SBA-15 before and after modification are shown in Figure 6. Large fibrous structures of 30–80 μm in length and 10–20 μm in diameter are clearly evident in Figure 6. Compared to the parent SBA-15, the size of the modified material decreased on both a microscopic and macroscopic scale, suggesting that the particle size can change on ultrasonication.

(a)

(b)

3.5. TEM

The TEM images in Figure 7 provide direct evidence that the material comprises well-ordered hexagonal arrays of mesopores (1D channel) and a 2D hexagonal structure [30]. The TEM image of Fe-SBA-15 (Figure 6(b)) shows that the structure is the same as in the parent SBA-15 silica. IR and nitrogen adsorption-desorption measurements confirmed that iron was doped in SBA-15. TEM and XRD results also confirmed that modification occurred within pores and that the SBA-15 structure did not change. The modified material retained the mesopore uniformity of the original inorganic wall structure of the parent SBA-15 silica [27].

(a)

(b)

3.6. Magnetic Behavior of Fe-SBA-15

Figure 8 shows that Fe-SBA-15 exhibited strong magnetic behavior with a magnetization value of 8.8 emu g^-1, confirming that Fe-SBA-15 was magnetic with potential as a magnetic adsorbent for removal of aromatic compounds from water.

Using AAS data, the iron content of Fe-SBA-15 was calculated as (), where is the sample absorbance and is the sample concentration. The iron load was thus determined to be 19.1 wt.% in the modified material, in accordance with its strong magnetic behavior.

There are two possible explanations for the strong magnetic behavior of Fe-SBA-15. First, Fe-SBA-15 was prepared with a high content iron. Second, iron may aggregate in SBA-15 channels during calcination and reduction. Large iron metallic particles that formed in Fe-SBA-15 can be observed in Figure 6(b).

3.7. Adsorption of Aromatic Compounds

Figure 9 shows the magnetic separation process for magnetic Fe-SBA-15. Fe-SBA-15 was fully dispersed by reciprocating oscillation. After 5 min, a magnet was fixed to the vessel wall to attract the material. Following the absorption process, Fe-SBA-15 was redispersed in methanol to desorb the aromatic compounds and the efficiency of magnetic separation was assessed by GC.

(a)

(b)

Analytical data for benzene, toluene, and ethyl benzene compared to standards revealed removal of 90.6%, 88.7%, and 85.4%, respectively, demonstrating that Fe-SBA-15 can be used as a sorbent in water. It is worth noting that Fe-SBA-15 can be reused after washing several times with methanol and vacuum drying.

4. Conclusions

Magnetic Fe-SBA-15 was prepared from mesoporous silica molecular sieves via a simple iron ion doping of SBA-15, transformation to Fe₂O₃ and then reduction to magnetic iron particles using H₂. Results confirm that the modified material retained the well-ordered hexagonal mesoporous structure after calcination at 800°C. Mesoporous silica materials may have further application potential, such as in sensing materials, solid supports, and nanobioelectronics, especially as magnetic sorbents allow the reuse of adsorbent materials for several cycles.

Acknowledgments

This work was supported by the National Natural Science Foundation of China (no. 20775029), the Program for New Century Excellent Talents in University (NCET-07-0400), and the Central Teacher Plan of Lanzhou University.

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Copyright © 2010 Huayu Huang et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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