Abstract
Graphene oxide (GO)–AgIO4 nanocomposites with excellent photocatalytic performance have been prepared through a facile ion-exchange method. The as-prepared samples are characterized by X-ray diffraction, Fourier transform infrared spectroscopy, scanning electron microscopy, and transmission electron microscopy. The GO–AgIO4 nanocomposites exhibit an enhanced photocatalytic activity in the degradation of organic pollutants as compared to bare AgIO4. It is revealed that the introduction of GO can relieve the agglomeration of AgIO4 particles, enhance the light absorption of the materials, and promote the separation of photoexcited electron–hole pairs. In addition, the possible transfer and separation behaviors of the charge carriers and the photocatalytic mechanism are discussed in detail. The excellent photocatalytic performance makes the GO–AgIO4 nanocomposites a promising photocatalyst for organic pollutant treatment.
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Introduction
Advanced oxidation processes, including Fenton [1,2,3] and photocatalytic oxidation [4], have been considered as promising treatment technologies for organic pollution removal because of their high removal efficiency than conventional methods. Among them, semiconductor photocatalysis was found to be prominent and practicable method for clean, economical, and environmentally friendly treatment of various organic pollutants by using solar energy [5,6,7]. Unfortunately, the most widely utilized photocatalyst of TiO2 is only active under UV irradiation [8]. Therefore, exploiting novel and efficient photocatalysts that can work under visible light is necessary for practical wastewater treatment. Plenty of efforts have been made to explore efficient visible-light-driven catalysts for the degradation of organic pollutants [9, 10]. However, the low photocatalytic activity and poor stability of these photocatalysts are the main problems that limit their practical application [11,12,13]. Therefore, it is still a challenge to develop new visible-light-driven photocatalysts with high photocatalytic activity and stability.
In recent years, graphene has been used as an ideal supporting material for photocatalysts due to its extraordinary properties such as super high surface area and excellent electron mobility [14,15,16]. A variety of graphene-based composite photocatalysts such as Ag2CO3–graphene [17, 18], Ag3PO4–graphene [19,20,21], AgX–graphene (X=Br, Cl), etc., have been reported [22,23,24,25,26]. These investigations found that graphene-based composite photocatalysts exhibit an enhanced photocatalytic performance in the degradation of organic pollutants as compared to their individual components. Thus, the preparation of graphene-based composite photocatalysts is a promising way to obtain high-efficient photocatalytic materials. Recently, Tang et al. [27] reported a novel AgIO4 photocatalyst with excellent photocatalytic activity. However, the graphene-based AgIO4 composite photocatalysts have not been reported so far. It is possible to further enhance the photocatalytic activity of AgIO4 by combining it with graphene.
Herein, we report an effective ion-exchange method to synthesize the composites of AgIO4 and graphene oxide (GO). The as-synthesized GO–AgIO4 nanocomposites exhibit enhanced photocatalytic performances compared to bare AgIO4 photocatalysts under simulated solar light (SSL) irradiation. In addition, the possible transfer and separation behaviors of the charge carriers and the photocatalytic mechanism are discussed in detail.
Experimental section
Materials
Natural flake graphite with a particle size of 150 μm (99.9% purity) was purchased from Qingdao Guyu Graphite Co., Ltd. All of the other chemical reagents employed in this study were obtained from Sinopharm Chemical Reagent Co., Ltd, which are of analytical grade and used as received without further purification. Graphite oxide was synthesized by a modified Hummers method [28, 29].
Synthesis of the photocatalysts
In a typical synthesis, a certain amount of graphite oxide was dispersed in 20 mL of distilled water by ultrasonication to give a GO dispersion. Then, 2 mmol of AgNO3 dissolved in 10 mL of distilled water was added into the GO dispersion. After the mixture was vigorously stirred for 2 h, 10 mL of Na2MoO4 (1 mmol) aqueous solution was dropwise added into the above mixture under stirring. After reacting for 30 min, 4 mmol of HIO4 was added and the resulted mixture was stirred for 1 h. The GO–AgIO4 product was collected by centrifugation, washed with water and absolute ethanol, respectively, and then dried at 45 °C in a vacuum oven. The synthetic process of GO–AgIO4 nanocomposites is illustrated in Fig. 1. To investigate the effect of the amount of GO on the photocatalytic activity of GO–AgIO4 composites, the GO–AgIO4 nanocomposites with GO contents of 0, 2, 7, and 10 wt% were prepared and denoted as AgIO4, 2%GO–AgIO4, 7%GO–AgIO4, and 10%GO–AgIO4, respectively. For comparison, the sample of AgIO4 (Ref) was prepared by the direct reaction of AgNO3 with HIO4 according to the method reported in literature [27]. In addition, partially reduced graphene oxide (pRGO)–AgIO4 and RGO–AgIO4 photocatalysts were also prepared according to the literature methods [30, 31].
Characterization
The phases of the as-obtained products were characterized by X-ray diffraction (XRD) on a Bruker D8 Advance diffractometer with Cu K α radiation (λ = 1.5406 Å) at a scanning rate of 7° min−1. The Raman spectra were acquired on a DXR Raman spectrometer with a 532 nm wavelength incident laser light at room temperature. The morphologies of the products were determined by scanning electron microscopy (SEM, JSM-6480) and transmission electron microscopy (TEM, JEOL JEM-2100). The loading amounts of AgIO4 in the GO/AgIO4 nanocomposites were examined by an inductively coupled plasma-optical emission spectrometer (ICP-OES, Vista-MXP, Varian). Fourier transform infrared (FT-IR) spectra were recorded on a Nicolet Nexus 470 spectrophotometer with KBr pellets in the 4000–400 cm−1 region. Ultraviolet–visible (UV–Vis) absorption spectra were recorded with a UV-1800PC UV–Vis spectrophotometer. UV–Vis diffuse reflectance spectra were conducted with a UV-2450 UV–Vis spectrophotometer. The photoluminescence properties of the samples were measured with a photoluminescence (PL) spectrometer (Varian Cary Eclipse).
Photocatalytic activity measurement
The photodegradation reaction was conducted in a GHX-3 photochemical reactor (Science and Education Equipment Co., Ltd, Yangzhou, China). A 250-W Xe lamp serving as the SSL source was positioned at ca.10 cm away from the reaction cell to trigger the photocatalytic reaction. The output wavelength spectrum of this lamp is shown in Fig. S1. There is a water layer between the reaction system and the lamp to remove the thermal effect of light. The photocatalytic activities of the samples were evaluated by the photocatalytic degradation of three different kinds of organic pollutants including methylene blue (MB), rhodamine B (RhB), and methyl orange (MO) under the SSL irradiation. Aqueous solutions (100 mL, 10 mg L−1) of MB, RhB, and MO were, respectively, used in the photodegradation processes. In each experiment, 10 mg of photocatalyst was added into the pollutant solution. Before illumination, the suspension was stirred in the dark for 1 h to ensure the establishment of an adsorption–desorption equilibrium between the photocatalyst and the pollutant. All the experiments were performed at 25 °C under constant stirring. At regular time intervals, 4 mL of the suspension was taken out from the reaction vessel and pipetted into a centrifuge tube. After centrifuged at 12000 rpm for 3 min to separate the remnant photocatalyst from the solution, the supernatant was taken out to determine its concentration by measuring its absorbance with an UV–Vis spectrophotometer. The characteristic absorption wavelengths of MB, RhB, and MO were 664, 554, and 464 nm, respectively. The photodegradation ratio was calculated using the relative concentration (C/C 0) of the organic pollutants, where C 0 is the calculated concentration of the organic pollutant after adsorption equilibrium, and C is the residual concentration at different irradiation time. In the recycle experiments, the photocatalyst was separated from the solution, washed with ethanol and DI water, and then re-dispersed in the dye solution for another cycle.
Results and discussion
Characterization of the as-prepared photocatalysts
X-ray diffraction (XRD) is used to investigate the crystalline phases of the as-synthesized samples, and the corresponding XRD patterns are shown in Fig. 2. For the AgIO4 sample, the peaks at 2θ of 18.1°, 29.6°, 33.3°, 38.1°, 47.9°, 56.2°, 61.3°, and 62.9° can be, respectively, indexed to (101), (004), (200), (211), (220), (312), (008), and (321) reflections of AgIO4 (JCPDS No. 10-0368). No any peaks from impurities can be observed in the XRD pattern, indicating that the AgIO4 sample is highly pure. It is interesting to note that the AgIO4 (Ref) prepared by the direct reaction of AgNO3 with HIO4 possesses a quite different crystal structure [27], which cannot be indexed to the AgIO4 standard card of JCPDS No. 10-0368. As usual, graphite oxide shows an intense diffraction peak at around 12°, corresponding to its (002) reflection [32]. The XRD pattern of 7%GO-AgIO4 nanocomposite is similar to that of AgIO4 sample, and no discernible diffraction peaks from graphite oxide are observed, which can be attributed to the low content of GO in these composites and/or the forestalled stack of GO sheets due to the attachment of inorganic units on them [33,34,35]. In addition, no observable shift in any of the AgIO4 reflections after combination with GO. These findings demonstrate that AgIO4 was not substituted into the position of oxide in GO, but rather presented as a discrete (predominantly) AgIO4 phase dispersed on the GO surface [4]. Raman spectroscopy is a powerful and nondestructive technique to investigate the structure of carbon-based materials. Figure 2b shows the Raman spectra of as-prepared AgIO4 and 7%GO–AgIO4 nanocomposite. It can be seen that besides the peaks from AgIO4, two prominent characteristic peaks can be observed in the Raman spectrum of 7%GO–AgIO4 nanocomposite, which are attributed to the well-documented D and G bands of GO. This further confirms the formation of GO–AgIO4 nanocomposite. Moreover, the AgIO4 peaks in 7%GO–AgIO4 show no appreciable shifts relative to those of pure AgIO4, further indicating negligible AgIO4 substitution into the position of oxide in GO.
FT-IR spectra were further used to analyze the compositions and structures of the as-synthesized samples. As shown in Fig. 3, in the FT-IR spectrum of graphite oxide, the broad band at 3250–3500 cm−1 is attributed to the stretching vibration of O–H groups [36], and the peak at 1375 cm−1 corresponds to the C–H bending [37]. In addition, the band corresponding to C=O stretching of –COOH groups is at around 1730 cm−1 and the band corresponding to O–H bending vibration appears at 1620 cm−1 [38, 39]. In the IR spectrum of 7%GO–AgIO4, except for the peaks from graphite oxide, other absorption peaks are similar to those of pure AgIO4. This result implies that the GO–AgIO4 nanocomposite has been successfully prepared.
The particle size and microstructure of the as-prepared AgIO4 and GO–AgIO4 nanocomposite were examined by SEM and TEM. Figure 4a, b shows the SEM image of pure AgIO4. The AgIO4 particles show big size and irregular morphology due to the severe agglomeration. As shown in the TEM images of GO–AgIO4 nanocomposites (Fig. 4c and Fig. S2), the transparent GO nanosheets are fully coated by AgIO4 particles, and AgIO4 particles exclusively anchor on GO nanosheets, suggesting the good combination of AgIO4 and GO. The mean particle sizes of the decorated AgIO4 in 2%GO–AgIO4, 7%GO–AgIO4, and 10%GO–AgIO4 nanocomposites are about 654, 514, and 353 nm, respectively. Notably, the diameter of the AgIO4 particles becomes much smaller than the pure AgIO4 particles. It is because GO nanosheets with large surface area can provide a great number of deposition sites for AgIO4 particles and thus prevent their agglomeration [35]. In order to determine the exact compositions of GO–AgIO4 nanocomposites, ICP-OES analysis was carried out. The GO contents in 2%GO–AgIO4, 7%GO–AgIO4, and 10%GO–AgIO4 nanocomposites were determined to be about 1.8, 6.6, and 9.5 wt%, respectively.
The optical absorption properties of the as-prepared photocatalysts are investigated by UV–Vis diffuse reflectance spectroscopy. As can be seen from Fig. 5a, compared to bare AgIO4, the 7%GO–AgIO4 nanocomposite shows much enhanced light absorption and a significant absorption-edge redshift, demonstrating that the introduction of GO into AgIO4 can largely improve the light absorption of the AgIO4 photocatalyst. Furthermore, the dynamics of separation and recombination of photoinduced electrons and holes of pure AgIO4 and 7%GO–AgIO4 nanocomposite was evaluated by PL spectroscopy. As shown in Fig. 5b, there are two main peaks at around 510 and 558 nm. Compared with those of GO and pure AgIO4, the intensities of the two peaks in the PL spectrum of 7%GO–AgIO4 nanocomposite obviously decrease, indicating lower recombination rate of photoinduced electrons and holes. The result suggests that the photoinduced electrons of pure AgIO4 could migrate to the GO nanosheets to reduce the subsequent electron–hole recombination [8]. In brief, after combining with GO, the charge separation of AgIO4 can be effectively improved, which could favor the enhancement of photocatalytic activity.
Photocatalytic activity
The photocatalytic activities of the as-prepared GO–AgIO4 nanocomposites were firstly evaluated by the degradation of MB under SSL irradiation at room temperature. As shown in Fig. 6, the blank test without any catalyst reveals that the self-photolysis of MB is negligible. The GO shows a poor photocatalytic activity. For pure AgIO4 catalyst, the degradation ratio of MB reaches 89.14% after 40 min of irradiation. However, only 41.25% of MB could be degraded by AgIO4 (Ref) within the same time. This suggests that a new AgIO4 photocatalyst with better photocatalytic activity is developed as compared to the reported AgIO4 (Ref) photocatalyst. The as-prepared GO–AgIO4 nanocomposite catalysts can exhibit further enhanced photocatalytic activities compared to bare AgIO4. With irradiation time of 40 min, the degradation ratios of 77.4, 97, and 94.7% can be achieved for 2%GO–AgIO4, 7%GO–AgIO4, and 10%GO–AgIO4, respectively. Therefore, the 7%GO–AgIO4 nanocomposite displays the highest photocatalytic activity. The photocatalytic performance of 7%GO–AgIO4 is also comparable to or even higher than that of previously reported GO-based photocatalysts such as GO/Ag@AgCl [31], GO/AgBr [23], GO/Ag/TiO2 [40], and Ag3PO4/graphene [20]. The dramatically enhanced photocatalytic activities of the GO–AgIO4 photocatalysts can be ascribed to the synergistic effect between GO and AgIO4. It is because GO nanosheets could effectively promote the charge carriers separation and transfer, which plays an important role in improving the photocatalytic activity [41, 42]. However, introduction of an excessive amount of GO may lead to covering the active sites on the surface of AgIO4, leading to a decrease in the photocatalytic activity, as evidenced by the 7%GO–AgIO4 and 10%GO–AgIO4 nanocomposites. Thus, the GO content has a significant influence on the photocatalytic activities of GO–AgIO4 composite photocatalysts.
The stability of the 7%GO–AgIO4 nanocomposite was investigated through the degradation of MB under the same condition for three successive cycles. The corresponding results are shown in Fig. 7a. After three recycling runs of the photodegradation of MB, the photocatalytic activity of 7%GO–AgIO4 nanocomposite shows only a little loss, and the photocatalytic degradation efficiency is still as high as 90.5% after reacting for 40 min, indicating the GO–AgIO4 nanocomposites possess good photocatalytic stability. As shown in Fig. 7b, the XRD pattern of the 7%GO–AgIO4 nanocomposites before and after photocatalytic reaction also shows that the crystal structure of AgIO4 has no obvious changes after the photocatalytic reaction. In addition, the structural stability of the photocatalysts after the catalytic reactions was also checked by TEM observation. As shown in Fig. S3, the morphology of the 7%GO–AgIO4 photocatalyst does not display noticeable changes after catalysis. The mean size of AgIO4 nanoparticles is 521 nm, which is consistent with the size before photocatalytic reaction. This further confirms the high stability of our prepared GO–AgIO4 nanocomposite.
The photocatalytic performances of the as-synthesized samples were also studied for the degradation of RhB and MO, and the results are shown in Fig. 8a, b, respectively. The blank tests indicate that the self-photolysis of RhB and MO can be ignored. GO also shows poor photocatalytic activity in the degradation of RhB and MO. It can be seen from Fig. 8a that with 40 min irradiation, 96.8% of RhB is degraded by 7%GO–AgIO4 catalyst, while for pure AgIO4, the degradation efficiency is only 87.2%, demonstrating the enhanced catalytic performance of 7%GO–AgIO4 for RhB degradation. A similar result is also found in the MO degradation. As shown in Fig. 8b, the photocatalytic activity of 7%GO–AgIO4 (79.4%) is much higher than that of bare AgIO4 (51.2%) in the MO degradation. It is worth noting that the GO–AgIO4 catalyst shows much better photocatalytic performance for the degradation of cationic dyes (MB and RhB) than the anionic dye (MO), which is probably due to the negative surface of GO nanosheets, which can easily adsorb the cationic dyes by the electrostatic force and effectively promote the charge carriers separation and transfer [43]. Therefore, on the basis of the photocatalytic degradation results, it could be concluded that the introduction of GO efficiently improves the photocatalytic activity of the AgIO4 photocatalyst. In addition, we also investigated the effect of the reduction degree of GO on the photocatalytic properties. As shown in Fig. S4, the AgIO4 supported on GO shows a higher photocatalytic activity than that supported on pRGO and RGO. The reduced photocatalytic performance can be attributed to the inevitably reduction of AgIO4 to Ag under the reduction process. The metal Ag on the surface of AgIO4 nanoparticles could cause a light shielding effect to prevent AgIO4 from absorbing light and also hinder the contact of MB molecules with AgIO4, thus decreasing their photocatalytic efficiency. Moreover, because oxygen atoms have a larger electronegativity than carbon atoms, GO could become a p-type material. After reduction, RGO only behaves as an electron conductor and does not contribute to the generation of electrons and holes by the absorption of light [31]. Thus, the photocatalytic activities of the 7%pRGO–AgIO4 and 7%RGO–AgIO4 nanocomposites are relatively lower than that of 7%GO–AgIO4.
Possible photocatalytic mechanism
As we known, organic dyes are photooxidized mainly by active species such as hydroxyl radicals (·OH), holes (h+) and superoxide radicals (O ·−2 ) [44]. To understand the photocatalytic reaction mechanism, we employed isopropanol (IPA), disodium ethylenediaminetetraacetate (Na2EDTA), and p-benzoquinone (BZQ) acting as ·OH, h+ and O ·−2 scavenger, respectively, in separate experiments. The results are shown in Fig. 9. It can be seen that when 10 mM IPA was added into MB solution, there is little effect on the photocatalytic activity of the GO–AgIO4 catalyst, while the addition of 1 mM of BZQ or 1 mM of Na2EDTA results in the fast deactivation of the catalyst. In particular, Na2EDTA can almost completely deactivate the catalytic process. The above results mean that h+ and O ·−2 contribute mostly to the photocatalytic process of the GO–AgIO4 nanocomposites.
Based on the above analysis, we propose the possible photocatalytic mechanism. As shown in Fig. 10, under light irradiation, the electrons (e−) at the valence band (VB) of AgIO4 are excited to the conduction band (CB), causing the formation of holes (h+) in the VB. Then, the electrons can reduce O2 into O ·−2 as the active species [45]; meanwhile, the holes can directly oxidize organic dyes. However, when AgIO4 particles are dispersed on the surface of GO nanosheets, these electrons on the CB of AgIO4 tend to transfer to GO nanosheets, leading to the hole–electron pairs to be separated more efficiently [35]. Thus, more electrons and holes can be utilized in the photodegradation process and the photocatalytic activity is improved.
Conclusion
In summary, a facile ion-exchange method has been developed for the synthesis of GO–AgIO4 composites. The GO–AgIO4 composites exhibit a significantly enhanced photocatalytic activity in the degradation of organic pollutants under SSL irradiation compared to the bare AgIO4. It is revealed that the content of GO has a significant influence on the photocatalytic performance of the GO–AgIO4 composites. The introduction of GO nanosheets could decrease the particle size of AgIO4, increase light absorption, and promote the effective separation of photoexcited electron–hole pairs. The graphene-based AgIO4 photocatalysts with excellent photocatalytic activity promise potential application in organic pollutant treatment.
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Acknowledgements
The authors are grateful for financial support from National Nature Science Foundation of China (Nos. 51272094, 51303204 and 51602129), the Natural Science Foundation of Jiangsu Province (No. BK20150507), Specialized Research Fund for the Doctoral Program of Higher Education of China (No. 20123227110018), China Postdoctoral Science Foundation (Nos. 2015M580392 and 2015M580393), and Jiangsu Planned Projects for Postdoctoral Research Funds (No. 1601231C).
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Ji, Z., Feng, L., Kong, L. et al. Synthesis of GO–AgIO4 nanocomposites with enhanced photocatalytic efficiency in the degradation of organic pollutants. J Mater Sci 52, 6100–6110 (2017). https://doi.org/10.1007/s10853-017-0849-4
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DOI: https://doi.org/10.1007/s10853-017-0849-4