Abstract
In this study, a novel graphene/Ag3PO4 quantum dot (rGO/Ag3PO4 QD) composite was successfully synthesized via a facile one-step photo-ultrasonic-assisted reduction method for the first time. The composites were analyzed by various techniques. According to the obtained results, Ag3PO4 QDs with a size of 1–4 nm were uniformly dispersed on rGO nanosheets to form rGO/Ag3PO4 QD composites. The photocatalytic activity of rGO/Ag3PO4 QD composites was evaluated by the decomposition of methylene blue (MB). Meanwhile, effects of the surfactant dosage and the amount of rGO on the photocatalytic activity were also investigated. It was found that rGO/Ag3PO4 QDs (WrGO:Wcomposite = 2.3%) composite exhibited better photocatalytic activity and stability with degrading 97.5% of MB within 5 min. The improved photocatalytic activities and stabilities were majorly related to the synergistic effect between Ag3PO4 QDs and rGO with high specific surface area, which gave rise to efficient interfacial transfer of photogenerated electrons and holes on both materials. Moreover, possible formation and photocatalytic mechanisms of rGO/Ag3PO4 QDs were proposed. The obtained rGO/Ag3PO4 QDs photocatalysts would have great potentials in sewage treatment and water splitting.
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Background
Recently, synthesis of photocatalysts with high efficiency has captured the attention of the researchers because of their potential applications in the removal of organic pollutants and hydrogen production [1,2,3]. Because of high activation and efficient separation of photoexcited electrons(e−) and holes(h+) [4], Ag3PO4 semiconductor photocatalysts received extensive attention of researchers in the field of photocatalysis. Unfortunately, there are several factors which influence the photocatalytic performance of Ag3PO4, such as irregular morphology, poor solubility, unstability, high cost, etc., which hindered its widespread applications [5]. Therefore, it is necessary to enhance the photoactivity and photostability of Ag3PO4.
Previous researches have proved that the photocatalytic performance could be significantly improved by the efficient separation of photogenerated e−-h+ pairs [6,7,8]. According to the equation τ = r2/π2D, where τ represents the average diffusion time of the photogenerated carriers, r stands for the particle radius, and D refers to the carrier diffusion coefficiency [9], reduced particle size may benefit for the efficient suppression of charge carrier recombination, thus improving the photocatalytic activity of the photocatalysts. It can be deduced from this viewpoint that the presence of quantum dots (QDs) could enhance the photocatalytic activity [10, 11]. Because surfactant coverage can hinder the mutual contact between QD surface and pollutants, QDs are seldom reported to be applied as high-efficient photocatalyst independently. In order to supplement this defect, QDs were usually loaded on a carrier with large surface area to decrease the aggregation in the absence of any stabilizer, which endows QDs with the enhanced photocatalytic activity.
Due to better electron separation and transfer in heterostructures, rGO was chosen to be the supporter for the Ag3PO4 QDs. rGO has a two-dimensional (2D) carbon structure with outstanding electronic, mechanical, and thermal properties [12], high specific surface area, and high carrier mobility [13,14,15,16].These properties make it a good substrate for Ag3PO4 photocatalyst, because it could effectively promote the e−-h+ pair separation and faciliate the charge transfer between the heterojunctions to improve photocatalytic activity and stability. Furthermore, rGO could be produced by a chemical oxidation and reduction procedure [17]. The methods of graphene oxide (GO) into rGO include chemical vapor deposition (CVD) reduction [18, 19], chemical reduction [20], and hydrothermal reduction [21, 22]. However, the above methods have some intrinsic drawbacks such as complex procedure and secondary pollution. Therefore, it is necessary to develop a green way to produce rGO. Recently, the new green ways of photo-assisted [23, 24] and ultrasonic-assisted [25] reduction method were reported.
Photoreduction of GO to produce rGO is a mild and green method; besides, photochemical and photothermal reduction mechanisms may take place individually or coinstantaneously in the processes [26,27,28]. Furthermore, the self-photoreduction of GO to rGO can enhance the presence of hole scavenger in the solution [24]. Ultrasound has been widely used for the material synthesis and wastewater treatment [29, 30].Ultrasonic irradiation can offer localized hot spots with pressure about 20 MPa, temperatures about 5000 K, and high cooling rate about 1010 Ks − 1, which are generated by acoustic cavitation [31]. Upon the ultrasonic irradiation, a variety of physical and chemical effects can be produced in the liquids by acoustic cavitation, and a unique chemical reactions environment can be provided under these extreme conditions [31, 32].However, to the best of our knowledge, the synthesis of rGO/Ag3PO4 QD composites using a photo-ultrasonic-assisted reduction method has not been reported yet.
Herein, we report the design and development of rGO/Ag3PO4 QD composites with high-efficient photocatalytic performance, wherein the Ag3PO4 QDs with a size of 1–4 nm were loaded uniformly on rGO nanosheets via a facile one-step photo-ultrasonic-assisted reduction method for the first time. The composites were analyzed by various techniques. The photocatalytic activity and stability of the obtained composites were evaluated by the degradation of methyl orange (MO), Rhodamine B (RhB), and methylene blue (MB) under visible light irradiation. Meanwhile, the surfactant dosage and the amount of rGO on the photocatalytic performance were also discussed. The possible photocatalytic mechanism of rGO/Ag3PO4 QDs was analyzed based on the free radicals trapping experiments. This paper will provide a facile and green method for the fabrication of multiple metal oxide QDs and efficient functional materials with broader application in the field of environmental purification.
Experimental Section
Synthesis of rGO/Ag3PO4 QDs
GO was prepared from natural graphite based on Hummers method [33]. In a typical synthesis process, 20 mg of GO was added in 50 mL of water and sonicated for 30 min to form a uniform suspension, and then 2.2 mmol sodium oleate was added into the above solution and sonicated for 60 min. After that, 10 mL AgNO3 aqueous solution(0.6 mol/L)was added, the obtained solution was stirred for 4 h to complete ion exchange, and then 10 mL Na2HPO4 aqueous solution (0.2 mol/L) was added drop by drop to the solution under ultrasonic irradiation. After 60 min, the precipitate was centrifuged (5000 rpm) for 5 min and washed several times with hexyl alcohol and absolute ethanol to obtain GO/Ag3PO4 QD composites. Hereafter, 0.3 g of GO/Ag3PO4QDs was dissolved in 100 mL absolute ethanol, and the mixture was exposed to visible light irradiation (CEL-S500, 300 W Xe lamp, 420 nm cutoff filter) and ultrasonic irradiation for 60 min. The ultrasonic irradiation was performed with a high-intensity ultrasonic probe (Xinzhi Co., China, JY92-2D, 10 mm diameter, Ti-horn, 20 kHz) which was placed in the reaction system. The precipitate was centrifuged (5000 rpm) for 5 min and then dried at 60 °C for 12 h to obtain rGO/Ag3PO4 QD composites. Ag3PO4 QDs were prepared under the same condition without GO. To investigate the optimal rGO loading amount, a series of samples with theoretical weight ratios of rGO to rGO/Ag3PO4 QD composites (WrGO:Wcomposite = 1.5, 2.0, 2.3, 2.5 and 3.0 wt%) were obtained. The corresponding rGO/Ag3PO4 QD composites were marked as R-1.5, R-2, R-2.3, R-2.5, and R-3.
Materials Characterization
Ag3PO4 QDs and rGO/Ag3PO4 QD composites were analyzed by X-ray diffraction (XRD, Cu-Ka, k = 1.5418 Å) in 2θ range from 10° to 80°, FT-IR spectroscopy, TEM (JEOL JEM-2010), Raman spectra system (Horiba JY-T64000, France), XPS (PHI Quantera SXM) spectrometer, and UV-vis spectrophotometer (U-3010, Hitachi, Japan). Photoluminescence spectra were obtained by FL (F-4500, Hitachi, Japan) spectrophotometer.
Photocatalytic Activity Measurement
To measure the photocatalytic properties of the composites, 10 mg of the prepared samples was added to 100 mL of 10 ppm MB. The mixture was magnetically stirred for 30 min under the dark to ensure absorption–desorption equilibrium. A filter (λ ≥ 420 nm) was placed on the beaker and then was irradiated with a 300 W xenon light source(CEL-S500, China). In the beginning, the samples were collected in every 1 minute, until 6 min, and then the samples were taken out in every 2 min. A UV-vis spectrophotometer was used to analyze the absorbance properties of the collected solution. The photocatalysts were removed by centrifugation (12,000 rpm, 3 min) before UV-vis measurements.
Detection of active species
The trapping experiment was conducted in a similar way with the photocatalytic degradation experiment. Three different scavengers including (concentration was about 1 mM) isopropanol (IPA, OH· scavenger), disodium ethylenediaminetetraacetate (EDTA, hole scavenger), and p-benzoquinone (BQ, O2·− scavenger) were used, respectively, to investigate the main active species generated in the photodegradation process.
Results and Discussion
Materials Characterization
Figure 1 exhibited the XRD patterns of GO, rGO, Ag3PO4 QDs, and R-2.3. The XRD results of GO and rGO revealed a characteristic reflection peak at 2θ = 10.7° and 25°, respectively (corresponding to a d-spacing of 0.83, 0.36 nm) (Fig. 1a, b) [34]. All the XRD peaks of Ag3PO4 can be indexed to the body-centered cubic phase of (JCPDS No.06-0505) (Fig. 1d). The R-2.3 exhibited a similar XRD pattern with pure Ag3PO4 QDs, and the broader diffraction peaks were attributed to the small size of Ag3PO4 QDs, which was calculated to be about 3.7 nm according to the Scherrer equation [35]. No diffraction peaks assigned to GO and rGO could be observed in the composites (Fig. 1c), which was attributed to the small rGO amount in the composite [36]. To investigate the effect of GO on the formation of Ag3PO4 QDs, the XRD pattern of pure Ag3PO4 QDs was measured. The diffraction peaks of pure Ag3PO4 QDs could be indexed to cubic Ag3PO4. The average size of pure Ag3PO4 QDs was calculated to be about 5.1 nm with the Scherrer equation, which was larger than that of rGO/Ag3PO4 composites. Above results indicated that GO sheets could affect the formation of Ag3PO4 QDs.
Figure 2 shows the TEM images of R-2.3 composites. Ag3PO4 QDs which a relatively narrow size distribution with a diameter of 2.81 ± 1.2 nm were dispersed uniformly on rGO sheet. The lattice spacing was 0.212 and 0.190 nm, which corresponded to the d-spacing of (220) and (310) crystallographic plane of Ag3PO4, respectively. To investigate the effects of ultrasonic, conventional stirring was performed instead of ultrasonic treatment. The results were shown in Additional file 1: Figure S1. Ag3PO4 particles on rGO which was formed by conventional stirring method did not show uniform structure, and the size of Ag3PO4 became larger than that formed by ultrasonic treatment. The above results indicated that ultrasonic treatment was very effective in dispersing and controlling size of Ag3PO4 particles on rGO layers [37].
The successful ultrasonic-assisted photo-reduction of GO to rGO can be further confirmed by XPS spectra of GO and R-2.3 composites as shown in Fig. 3. The peaks located at 131.7, 284.2, 367.2, and 530.2 eV were indexed to the characteristic peaks of P2p, C1s, Ag3d, and O1s, respectively (Fig. 3a). The strong peaks at 366.8 and 372.8 eV are attributed to Ag+ of Ag3PO4 [38] (Fig. 3b). The O1s XPS spectra of R-2.3 can be divided into two peaks, which were attributed to O1s from Ag3PO4 (529.5 eV) and O1s from rGO (531.3 eV) [7, 39]. The peak of O1s from rGO (531.3 eV) shifted to lower binding energy compared with that of GO (531.8 eV), implying that there existed a chemical interaction between rGO and Ag3PO4 QDs by C=O bond. The C1s spectrum of GO was divided into three different peaks at 284.8, 286.7, and 287.7 eV, which were assigned to C-C/C=C, C-O, and C=O, respectively [40, 41] (Fig. 3c). After being reduced by visible light assisted with ultrasonic irradiation (Fig. 3d), the oxygen-containing groups, especially C-O, C=O showed remarkably decreased peak intensities, indicating that the reduction from GO to rGO proceeded successfully.
Figure 4a demonstrated the FTIR spectra of GO, rGO, Ag3PO4 QDs, and R-2.3. The characteristic peaks at 1725.6, 1056.5, and 1615.4 cm− 1 in GO were attributed to the stretching vibrations of carboxyl C=O, alkoxy C-O, and C=C [40, 42], respectively. The broad peak at 3000–3600 cm− 1 was ascribed to the O-H stretching vibration [43]. Ag3PO4 QDs and R-2.3 composites had similar FT-IR peaks at 552.1 and 970.2 cm− 1, which were assigned to vibrations of P-O from PO43− [44]. This indicated that Ag3PO4 QDs were bonded on rGO sheets. After photo-ultrasonic-assisted reduction to rGO, the characteristic peaks (at 1725.6, 1056.5 cm− 1) shifted to lower wavenumbers compared to GO, which was consistent with the results of XPS analysis, indicating the existence of charge interaction between rGO and Ag3PO4 in the as-prepared composites.
Figure 4b showed the Raman spectra of GO, rGO, Ag3PO4 QDs, and R-2.3. The Raman spectrum of GO showed two characteristic peaks of the D band at 1347 cm− 1 and G band at 1586 cm− 1. The value of ID/IG in R-2.3 and in GO was about 1.039 and 0.9056, respectively. It was obvious that the composite showed relatively high intensity of the D band compared with GO, which confirmed that the GO sheets were partially reduced into rGO [37]. The Raman spectra of Ag3PO4 QDs and R-2.3 showed three distinct peaks at 410, 566, and 714 cm− 1, and these peaks were accredited to the P-O-P bonds. The strong peak at 907 cm− 1 was raised from the motion of terminal oxygen bond vibration in phosphate chains [23].
Preparation mechanism of rGO/Ag3PO4 QDs
The synthesis route of rGO/Ag3PO4 QD composite was proposed and schematically illustrated in Fig. 5. The synthesis reactions were detailed as follows:
The total synthesis route could be fallen into four successive stages. Firstly, Ag+ and oleate ions interacted electrostatically to form Ag-oleate complexes, hydrolysis of Ag+ ions could be prevented effectively by this process. Ag-oleate complexes interacted with the excess of oleate ions improving its hydrophilic property in order to disperse in water. Oxygen groups on the surface of GO provided hydrophilic property. When GO sheets were added to the Ag- oleate aqueous solution, the Ag-oleate complexes will preferentially adsorb on these oxygen containing functional groups (Eq. (1)). Secondly, reactions between Ag+ and PO43− proceeded to form Ag3PO4 QDs on GO surface (Eq. (2)). Thirdly, when GO-Ag3PO4 QDs were sonicated in solution, the ultrasonic stimulated electron–hole pairs from Ag3PO4 QDs when GO-Ag3PO4QDs was irradiated with visible-light in ethanol solution. At the same time, ·H and H2O2 were produced by ultrasonic irradiation. Ultimately, GO was reduced into rGO by ·H and accepted photo-generated electrons from the conduction band (CB) of Ag3PO4. As a result, rGO/Ag3PO4 QD composite was obtained by photo-ultrasonic-assisted reduction.
Optical properties of photocatalysis
The UV-vis absorption spectra of Ag3PO4 QDs and rGO/Ag3PO4 QDs with different mass ratio of rGO were shown in Fig. 6a. The absorbance wavelength of pure Ag3PO4 QDs was shorter than 530 nm; inversely, rGO/Ag3PO4 QD composites structure showed an extended wavelength (> 530 nm) and its intensity increased with increasing rGO contents before which reached 2.3%, and decreased after. This can be attributed to that the presence of carbon in rGO/Ag3PO4 QDs reduces the reflection of light [45]. According to the Kubelka–Munk function [46], we can get the band gaps of the photocatalysts as shown in Fig. 6b and Additional file 1: Figure S2; the band gap of R-2.3 was calculated to be 1.62 eV, which was lower than pure Ag3PO4 QDs (2.23 eV). The relative narrow band gap energy may be attributed to the synergetic effect that sum of the total effect is superior to the single effect after different types of dispersion to interact between rGO and Ag3PO4 QDs [47], which lead to improve the solar spectrum utilization efficiency of the photocatalysts [36].
Photocatalytic activity and stability
To understand the influencing factors on the experimental process to the photocatalytic activity, the effects of different mass of surfactant were investigated as shown in Additional file 1: Figure S3. Samples were prepared when other conditions remained constant. The result showed that the photocatalytic activities increased with increasing the mass of surfactant but decreased after more than 0.5 g, as shown in Additional file 1: Figure S3, which may be ascribed to the excessive oleate ions that limited Ag3PO4 QDs size distribution on rGO surface [35]. This leads to the decrease of photocatalytic activities. Compared with pure Ag3PO4 QDs, the concentration of MB decreased rapidly for rGO/Ag3PO4 QD composites (Fig. 7a). This result indicated that the photocatalytic reaction was related to the existence of active sites [48, 49]. When the content of rGO was 2.3%, the highest photocatalytic activity was emerged and could degrade MB by 97.46% for 5 min. This can be attributed to rGO-semiconductor heterojunction, which had effectively availed the transfer of charge from rGO nanosheets under visible light irradiation [23]. Under the same conditions, when increasing the content of rGO to 3%, the results had proved fact that excessive loading of rGO could reduce the dye and photon absorption on Ag3PO4 [23]. Importantly, rGO/Ag3PO4 QD composites displayed superior photocatalytic performance than pure Ag3PO4 QDs and rGO-based Ag3PO4 composites [23, 50]. The photoexited electrons(e−) could transfer from the CB of Ag3PO4 QDs to rGO, and rGO in the composites could act as a highway for electron transfer to suppress the e−-h+ recombination, which accounted for the remarkably improved photo-conversion efficiency [51]. Moreover, interfacial charge transfer could be faciliated due to the larger superfacial area of rGO [52, 53]. On top of that, the photocatalytic degradation efficiency of R-2.3 composite over different organic dyes was investigated as shown in Additional file 1: Figure S4.
To test the stability of the R-2.3 composite, the cycling experiments of the composite for MB were performed (Fig. 7c). The results revealed that R-2.3 composites exemplified higher photocatalytic stability after five cycles, with maintaining its degradation efficiency up to 90%, indicating the good photocayalytic stability. And this may be benefited from the efficient photo-generated e−-h+ separation. Moreover, the XRD pattern of R-2.3, which was used for five cycles is shown in Fig. 7d, and no obvious peak about Ag is observed this may be attributed to that rGO could facilitate the electron transfer to Ag3PO4 QDs and decreased the photocorrosion of Ag3PO4 QDs [23].
Mechanism of the enhanced photocatalytic performance
The aforementioned experimental results indicated that the photocatalytic performance of Ag3PO4 was enhanced by combining Ag3PO4 with rGO sheets, which was ascribed to the fast transfer and separation of photo-generated e−-h+ pairs in the composites [23]. The photoluminescence (PL) spectra were performed to investigate the e−-h+ pairs migration, transfer, and recombination processes in semiconductors [54, 55]. Figure 8a showed the PL spectra of the samples. The PL spectra of rGO/Ag3PO4 QDs showed a lower recombination rate of photogenerated e−-h+ pairs compared to Ag3PO4 QDs, indicating that more photogenerated e− and h+ can participate in the reduction and oxidation reaction; this could lead to decline of the recombination of photogenerated e−-h+ pairs in Ag3PO4 in the composites. Therefore, rGO/Ag3PO4 QD composite displayed superior photocatalytic activity than that of Ag3PO4 QDs.
To further confirm the main active species in the photocatalysis process over rGO/Ag3PO4 QDs, MB was used as a pollutant. The results are shown in Fig. 8b. Herein, after the addition of isopropanol (as hydroxyl radical scavenger) [56], the catalytic activity of rGO/Ag3PO4 QDs was not obviously affected; when EDTA (as hole capture) [57] was added, the photocatalytic degradation of MB was greatly inhibited. However, when p-benzoquinone (BQ, O2·− scavenger) was added, the deactivation of rGO/Ag3PO4 QDs was unneglectable. The above results illustrated that holes and O2·− radicals were the main active species in the photocatalysis process.
The mechanism for the photocatalytic degradation of organic dyes by rGO/Ag3PO4 QDs is shown in Fig. 9. Upon the visible light exposure, Ag3PO4 QDs was photoexcited, and electrons were excited from valence band to conduction band; after that the electrons could transfer to rGO due to effect of the electric field, and then electrons retransferred to the surface of rGO to participate in the photocatalytic reaction. rGO could efficiently separate e−-h+ pairs, thus availed the transfer of the electrons [23] and led to the promoted photocatalytic activity of rGO/Ag3PO4 QD composites.
Conclusions
A novel rGO/Ag3PO4 QD composite was prepared via a facile photo-ultrasonic-assisted reduction method. The obtained rGO/Ag3PO4 QD composites exhibited better photocatalytic activity under visible light and higher than pure Ag3PO4 QDs alone. This was due to the efficient e−-h+ pairs separation and fast electron transfer in these heterojunctions. The rGO sheets effectively promoted the separation of e− and h+ and fast transfer of electrons in the heterostructure photocatalysts. Free radicals trapping experiments indicated that h+ played important roles in the photocatalytic degradation of dyes. It was clear that ultrasonic-assisted method was a facile and economical way to prepare visible-light-responsive and high efficient Ag3PO4 QDs-based composites.
Abbreviations
- 2D:
-
Two-dimensional
- BQ:
-
p-benzoquinone
- CB:
-
Conduction band
- CVD:
-
Chemical vapor deposition
- EDTA:
-
Disodium ethylenediaminetetraacetate
- GO:
-
Graphene oxide
- IPA:
-
Isopropanol
- MB:
-
Methylene blue
- MO:
-
Methyl orange
- QDs:
-
Quantum dots
- R-1.5, R-2, R-2.3, R-2.5, and R-3:
-
Content of rGO in composites 1.5, 2.0, 2.3, 2.5, and 3.0 wt%
- rGO:
-
Graphene
- RhB:
-
Rhodamine B
- Wcomposite :
-
Weight of composites
- WrGO :
-
Weight of grapheme
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Acknowledgements
This work was supported by the Dr. Startup funds of Xinjiang University (BS150223) and National Natural Science Foundation of China (No. 21465022).
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AR has carried out the interpretation of all the data such as the XRD, XPS, Raman patterns, TEM images, and photocatalic degradation experiment. He also proposed the photocatalytic mechanism. YT, TD, and MH have contributed in observing the morphology and crystal structure of rGO-Ag3PO4 composite and studied on the formation mechanism. KK has contributed in testing the data of PL, UV-vis, and grammar correcting of all text. AA designed the research work. All authors read and approved the final manuscript.
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Figure S1. TEM images of rGO/Ag3PO4 QDs (stirring method). Figure S2. The plots of (αhν)2 versus Eg of Ag3PO4 QDs, R-1.5, R-2, R-2.3, R-2.5, and R-3. Figure S3. (a) Photocatalyticdegradation of MB by R-2.3 prepared by different mass of surfactant and (b) apparent rate constants (k) of samples for photocatalytic degradation of MB. Figure S4. (a) Photocatalytic degradation of MB, MO, and RhB byR-2.3, (b) apparent rate constants (k) of sample for photocatalytic degradation of dyes. (ZIP 12230 kb)
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Reheman, A., Tursun, Y., Dilinuer, T. et al. Facile One-Step Sonochemical Synthesis and Photocatalytic Properties of Graphene/Ag3PO4 Quantum Dots Composites. Nanoscale Res Lett 13, 70 (2018). https://doi.org/10.1186/s11671-018-2466-9
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DOI: https://doi.org/10.1186/s11671-018-2466-9