Abstract
The g-CNQDs/H3PW12O40/TiO2 heterojunction photocatalytic material is fabricated by facile ultrasonic method. The crystal structure, elemental composition, morphology and optical properties of as-synthesized catalysts are investigated by a series of characterizations. Studies have shown that g-CNQDs have been successfully doped into H3PW12O40/TiO2. The introduced g-CNQDs are uniform in size and have an average diameter of 5.8 nm. The 5% g-CNQDs/H3PW12O40/TiO2 shows the highest degradation efficiency of 99.3% toward RhB under simulated sunlight for 30 min, which is 5.68 times than of H3PW12O40/TiO2 under same conditions. The improved photocatalytic activity of the g-CNQDs/H3PW12O40/TiO2 ternary system is attributed to the expansion of visible-light absorption region and diminishing photoelectron–hole recombination. The testing of radical scavengers demonstrated that the main active species in the photocatalytic process involving three active species are ·O2− and ·OH, and the holes (h+VB ) play an auxiliary role. The photodegradation efficiency of g-CNQDs/H3PW12O40/TiO2 ternary composite catalyst is reduced by 6.2% after five cycling runs. The present work proposes an efficient optimization of the fabrication of potent and stable TiO2-based photocatalysts driven by sunlight.
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Introduction
The exploitation of semiconductor photocatalysts driven by sunlight has become a trend to mitigate the energy and environment situation [1,2,3,4,5]. TiO2 photocatalyst is popular for degrading organic contaminants in virtue of oxidation power, stability, low cost and non-toxic. However, the practical application of TiO2 remains limited due to poor quantum yield and wide bandgap [6, 7]. Up to now, numerous strategies have been demonstrated to boost the catalytic activity of TiO2. Among them, the design of TiO2-based heterostructures [8,9,10,11] has been a feasible and efficient strategy to surmount the shortcomings of fast photoinduced carriers’ recombination and restricted visible-light response of TiO2. Yi et al. [12] demonstrated that Bi2Ti2O7/TiO2 heterostructures with higher photodegradation efficiency are attributed to enhanced light-harvesting and efficient carrier transfer. Nevertheless, the construction of TiO2-based photocatalytic materials still exists restriction in degrading organic contaminants.
Graphitic carbon nitride (g-C3N4) is a class of metal-free photocatalyst with a narrow bandgap of 2.70 eV, which allows it to absorb visible-light without modification [13]. G-C3N4 exhibits superiority in terms of photodegradation of organic contaminants and hydrogen production by water decomposition [14]. However, currently available g-C3N4 materials are typically sub-micrometer sized. Low dimensionalization of g-C3N4 forms g-C3N4 quantum dots (abbreviated as g-CNQDs), which possess up-conversion luminescence effect [15,16,17,18,19,20]. Howbeit, it has limited efficiency of directly utilize g-CNQDs for organic contaminants photodegradation. To build a composite system with g-CNQDs and other vectors, we utilized the up-conversion characteristics of g-CNQDs to convert long-wave illumination light into shorter-wavelength emission light for composite materials [21]. Meanwhile, the heterojunction generated after recombination can facilitate photoinduced carriers’ separation. Accordingly, it would contribute to the development of g-CNQDs load materials for photocatalytic applications. Many reports focused on various loaded g-CNQDs heterostructures lately, such as g-CNQDs/g-C3N4, g-CNQDs/graphene and BiVO4/CNQDs/NCDs [22,23,24]. Su et al. [25] confirmed that g-CNQDs/TiO2 nanotube arrays (NTAs) heterojunction displays better photocatalytic performance in the decomposition of rhodamine B (RhB) and put it down to enhanced light absorption and the migration of light-excited electrons from g-CNQDs to TiO2. Nevertheless, the photodegradation efficiency of g-CNQDs/TiO2 needs to go one step further.
Herein, we carried on a successful attempt at the preparation of g-CNQDs/H3PW12O40/TiO2 ternary hybrids via coupling g-CNQDs with H3PW12O40/TiO2 by facile ultrasonic method. The introduction of g-CNQDs and H3PW12O40 significantly boosts the photocatalytic activity of TiO2. H3PW12O40, as one type of significant transition metal-oxide clusters with multiple topologies and high valence negative ion charges, has been considered as a dual-function green catalyst with redox characteristics and electron capture capacity [26, 27]. H3PW12O40 combines with TiO2 can diminish photogenerated carriers’ recombination rate in virtue of the outstanding electron acceptability of Keggin units [28]. In terms of H3PW12O40/TiO2 composite, the restricted UV-light response results in a corresponding low solar utilization. In this context, we further doped g-CNQDs to construct g-CNQDs/H3PW12O40/TiO2 heterostructure stems from several considerations: (1) wide bandgap semiconductor coupled with narrow bandgap semiconductor can effectively enhance its visible-light absorption owing to the synergic absorption effect in a heterojunction. (2) matching band edge position among distinct materials greatly facilitates the separation and transmission of photoinduced electron–hole, thereby increasing quantum efficiency. (3) the up-conversion effect of g-CNQDs increases UV-light intensity to some extent. The crystal structure, elemental composition, morphology and optical properties of as-synthesized catalysts were characterized. The catalytic activity of ternary composite was assessed by measuring the decomposition of RhB under simulated sunlight (320 nm < λ < 780 nm). And then the photodegradation reactions of TiO2, g-CNQDs, H3PW12O40/TiO2, g-CNQDs/TiO2 were also compared. Photoluminescence (PL) analysis and photoelectrochemistry (PEC) measurements were performed to disclose the migration and separation efficiency of light-excited charge carriers among composite materials. Beyond that, the active species formed in the process of photodegradation were the possible reaction mechanism of g-CNQDs/H3PW12O40/TiO2 system. Last but not least, we made recycling experiments to validate the stability and reusability of the ternary composite under identical reaction conditions.
Experimental section
Preparation of g-CNQDs
Solid-phase reaction method: 1.01 g of urea and 0.81 g of sodium citrate were first placed in an agate mortar and continuously ground for half an hour before placed in a high temperature reaction kettle and then placed the mixture in a temperature-programmed box and heated to 180 °C for 1 h. After taking out, it was cooled to room temperature and then dried in a dry box for 6 h to obtain a g-C3N4 nano material. Next, the obtained g-C3N4 nanomaterial was ground into powder using a mortar and centrifuged at 8000 rpm for 10 min with ethanol dispersion. The procedure was repeated three times to remove some unreacted precursor, and finally, the obtained solid was charged into 1000 Da. The dialysis bag was dialyzed in water for 24 h, and the obtained product was freeze-dried for 24 h to obtain pure g-CNQDs material.
Preparation of g-CNQDs/H3PW12O40/TiO2
The fabrication of H3PW12O40/TiO2 was conducted by sol–gel method following the literature [29]. A certain amount of H3PW12O40/TiO2 binary catalyst powder and g-CNQDs powder were weighed and mixed well, and the mixture was added to 30 mL distilled water. The suspension was stirred for 30 min and ultrasound for another 30 min. The above process repeated twice. The obtained solution was allowed to settle in a closed and dry environment for 12 h. The mixed solution was placed in a constant temperature drying oven and dried at 80 °C for 12 h, and then fully ground into powder to obtain a g-CNQDs/H3PW12O40/TiO2 ternary composite catalyst. The mass ratio of g-CNQDs to H3PW12O40/TiO2 was 3%, 5% and 10%, respectively.
Catalyst characterizations
The crystalline structure of as-synthesized samples was presented on Ricoh Y-2000 X-ray powder diffractometer. The FTIR spectrum texts were actualized on Nicolet 360 spectrometer with distinct samples dispersed in KBr desiccative. Transmission electron microscopy (TEM) images were acquired on JEOL Hitachi-600. X-ray photoelectron spectroscopes (XPS) were measured on a VG-ADES 400IR spectrometer with Mg K-ADES source at a residual gas pressure that below 10−8 Pa. The resolution limitation of XPS is 0.65 eV. UV–vis absorption spectra were obtained using a Cary 500 UV–vis–NIR spectrophotometer. The specific surface areas and pore size distribution of catalysts are determined by V-SORB2802 analyzer at 77 K. PL spectra of distinct samples are conducted on FL 7000 fluorescence spectrometer at room temperature. Photocurrent experiments were actualized on CHI 630E electrochemical station.
Photocatalytic experiments
The photocatalytic activity of g-CNQDs/H3PW12O40/TiO2 composite was investigated by degrading RhB. The photocatalyst (50 mg) was added to aqueous solution of RhB (50 mL, 20 mg L−1). Prior to the start of the photocatalytic experiment, the solution was mechanically stirred for a certain time to achieve adsorption–desorption equilibrium. Then, we turn on the xenon lamp to simulate sunlight source and stirring was continued throughout the reaction to bring the catalyst into full contact with the RhB solution. Samples were taken every 5 min and the samples were immediately filtered through a 0.22 μm pinhole filter to remove the catalyst. The absorbance of each sample was measured by a UV–Vis spectrophotometer at 553 nm, and the degradation rate was converted by the absorbance ratio.
Results and discussion
Characterization
Figure 1 exhibits the XRD patterns of as-synthesized catalysts. The anatase TiO2 standard cards have diffraction peaks at 25.4° (101), 38.1° (004), 48.0° (200), 54.0° (105) and 55.2° (211), respectively (JCPDS No. 21-1272). The catalysts containing TiO2 in the figure have identical characteristic diffraction peaks of anatase crystal form, which indicates that the TiO2 in the composite prepared by sol–gel method belongs to anatase phase [30]. The doping amount of H3PW12O40 or g-CNQDs does not change its crystalline structure. No characteristic diffraction peak of H3PW12O40 can be observed, since only a small amount of H3PW12O40 content distributed in TiO2 material. For pure g-CNQDs, 27.2° (d = 0.336 nm) corresponds to the (002) plane of hexagonal graphitic C3N4 (JCPDS No. 87-1526) [31]. This indicates that the fabricated g-CNQDs have graphite phase crystal forms. No characteristic peak of g-CNQDs can be observed in 5% g-CNQDs/H3PW12O40/TiO2, which may due to the relatively small doping amount of g-CNQDs. The 10% g-CNQDs/H3PW12O40/TiO2 shows a characteristic peak of g-CNQDs at 27.2°, which indicates that g-CNQDs has been successfully loaded into H3PW12O40/TiO2. In 10% g-CNQDs/TiO2, characteristic peaks of TiO2 and g-CNQDs appear simultaneously as well.
As shown in Fig. 2, the prepared TiO2, H3PW12O40, g-CNQDs, H3PW12O40/TiO2, 10% g-CNQDs/TiO2 and 10% g-CNQDs/H3PW12O40/TiO2 catalysts are subjected to FTIR test analysis. For pure TiO2, the characteristic peak at 450.4 cm−1 is assigned to Ti–O–Ti bond stretching vibration in anatase crystals [32]. In the FTIR spectrum of g-CNQDs, the peak at 803 cm−1 is attributed to the CN heterocycle of triazine units in g-CNQDs [33]. Several strong characteristic peaks at 1237, 1317, 1411, 1470, 1565 and 1638 cm−1 correspond to the typical stretching modes of CN heterocycle [34, 35]. A broad absorption band from 3100 to 3400 cm−1 represents NH groups’ stretching vibration [36]. The characteristic peaks of TiO2 and g-CNQDs appear simultaneously in the composites g-CNQDs/TiO2 and g-CNQDs/H3PW12O40/TiO2, indicating that g-CNQDs have been successfully loaded into the target material. In addition, the vibration absorption peak positions of the P–O, W=O and W–O–W bonds should be at 1085, 962 and 893 cm−1, respectively [37, 38]. However, these characteristic peaks are weak in H3PW12O40/TiO2 and 10% g-CNQDs/H3PW12O40/TiO2 due to the low dosage of H3PW12O40.
XPS is used to detect the chemical composition of the surface and determines the chemical state of each element of as-prepared catalysts. The survey spectrum in Fig. 3a reveals the presence of C, N for g-CNQDs; Ti, O, W for H3PW12O40/TiO2; C, N, Ti, O, W for g-CNQDs/H3PW12O40/TiO2 composite. Figure 3b shows the high-resolution XPS spectrum of C1s. The peaks at 284.6 eV and 287.6 eV in g-CNQDs are derived from sp2-hybridized carbon atoms in graphite phase and sp3-bonded carbon in C-N of g-CNQDs [39]. As shown in Fig. 3c, the N 1s peak in g-CNQDs can be divided into two peaks at 398.4 eV and 399.9 eV, which are assigned to triazine rings (C–N–C) and tertiary nitrogen (N–C3), respectively [40]. The binding energy values in 5% g-CNQDs/H3PW12O40/TiO2 (288.1 eV, 398.6 eV and 400.0 eV) exhibit certain positive displacements in contrast to those of C, N in g-CNQDs (287.6 eV, 398.4 eV and 399.9 eV), which indicates robust interaction among composite materials. Figure 3d shows the XPS spectrum of O1s where three characteristic peaks appear at 529.7 eV, 531.4 eV and 532.8 eV, respectively. The peaks at 529.7 eV and 531.4 eV belong to lattice oxygen of anatase TiO2 and Keggin unit of H3PW12O40, and the physical-absorption water of 532.8 eV [41]. Compared to H3PW12O40/TiO2 (529.8 eV, 531.7 eV), the binding energy values of oxygen in g-CNQDs/H3PW12O40/TiO2 (529.7 eV, 531.4 eV) show negative deviations, implying the interaction between g-CNQDs and H3PW12O40/TiO2. As shown in Fig. 3e, the peaks located at 458.4 eV and 464.0 eV correspond to Ti 2p3/2 and Ti 2p1/2, respectively, which indicates that Ti element presents in the form of high-value oxidation state Ti4+ [42]. The binding energy value of titanium in 5% g-CNQDs/H3PW12O40/TiO2 (464.4 eV) increases 0.2 eV in comparison with that of H3PW12O40/TiO2 (464.2 eV), further confirmed the interaction between g-CNQDs and H3PW12O40/TiO2 in the composite. In Fig. 3f, we can see that the peaks located at 34.80 eV and 36.80 eV relate to W 4f7/2 and W 4f5/2, respectively, and the W element has the highest oxidation state [W(VI)] [43]. It is notable that the O, Ti and W binding energies in H3PW12O40/TiO2 display certain displacements than those of pure TiO2 and H3PW12O40, which confirms the formation of Ti–O–W chemical bonds [44]. Due to the low content of P element in H3PW12O40/TiO2, it is not detected by the machine. The above results indicate that H3PW12O40/TiO2 is successfully combined with g-CNQDs.
The TEM researches the morphology of as-synthesized catalysts. In order to control the morphology and size of g-CNQDs, three methods, acid etching, evaporation condensation and solid-state reaction, were used to prepare g-CNQDs. As shown in Figure S1 (a–c), the morphology and size of g-CNQDs prepared by solid-phase reaction method are very uniform. Therefore, the solid-state reaction method was selected as the method of preparing g-CNQDs. The carbon nitride quantum dots are well dispersed and uniform in size, and the particle sizes are mostly around 3–9 nm with an average size of 5.8 nm (Fig. 4a and S1d). H3PW12O40/TiO2 has a particle size of about 10-–0 nm (Fig. 4b). It can be observed that g-CNQDs are loaded on the surface of H3PW12O40/TiO2 composite (Fig. 4c). By measuring the lattice fringes in Fig. 4d, the interplanar distances are approximately 0.353 nm and 0.336 nm, corresponding to the (101) plane of anatase TiO2 and the (002) plane of g-CNQDs, respectively. Their close combination demonstrates the formation of a heterojunction between g-CNQDs and TiO2.
The N2 adsorption–desorption isotherms of g-CNQDs, H3PW12O40/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 are shown in Fig. S2. The g-CNQDs show type-IV isotherms with H3 hysteresis loop according to the IUPAC classification, which is related to the characteristic capillary condensation within the mesopore channels. The BET surface areas of g-CNQDs, H3PW12O40/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 are 184.6, 72.2 and 94.3 m2/g, respectively. In comparison with H3PW12O40/TiO2, the larger surface area of g-CNQDs/H3PW12O40/TiO2 is expected to provide more active sites for photocatalytic reaction.
The optical properties of photocatalyst exert a significant function in determining its photocatalytic performance toward organic contaminants. The light absorption capacity of as-prepared samples is measured by UV–Vis DRS (Fig. 5). For g-CNQDs, the absorption boundary is approximately 450 nm, and the bandgap is estimated to be 2.73 eV, which is consistent with previous reports [45]. Due to the influence of g-CNQDs quantum size effect, it is blueshifted relative to g-C3N4 (Fig. S3). There is a strong absorption region of TiO2 among 200–400 nm in virtue of the electronic transition from O 2p orbitals to Ti 2p orbitals [46]. The absorption boundary of H3PW12O40/TiO2 has a blueshift compared with TiO2, which is attributed to the smaller particle size of H3PW12O40/TiO2 [47]. 5% g-CNQDs/TiO2 redshifted compared to pure TiO2, due to the electronic interaction between TiO2 and g-CNQDs. 5% g-CNQDs/H3PW12O40/TiO2 redshifted as well, indicating higher separation efficiency of photoinduced carriers. The bandgap energy of 5% g-CNQDs/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 composite catalysts is gradually reduced, which improved the photon efficiency of the system. According to the Kubelka–Munk function [48], the bandgaps of g-CNQDs, TiO2, H3PW12O40/TiO2, 5% g-CNQDs/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 are estimated to be 2.73 eV, 3.06 eV, 3.08 eV, 2.91 eV and 2.86 eV, respectively.
The study of photocatalytic activity
The photocatalytic performances of synthetic materials are investigated by measuring the decomposition of RhB under simulated sunlight (320 nm < λ < 780 nm). All photocatalytic activity tests are performed after the adsorption equilibrium is reached. In Fig. 6a, all catalysts reach adsorption equilibrium after 60 min in dark. The adsorption rates of g-CNQDs, P25, H3PW12O40/TiO2, 5% g-CNQDs/TiO2, 3% g-CNQDs/H3PW12O40/TiO2, 5% g-CNQDs/H3PW12O40/TiO2 and 10% g-CNQDs/H3PW12O40/TiO2 are 13.2%, 11.2%, 11.7% 14.2%, 15.3%, 15.9% and 16.7%, respectively. The introduction of g-CNQDs enhances the adsorption capacity of H3PW12O40/TiO2 and raises specific surface area after compounding facilitates the capture of contaminants. Direct photolysis of RhB without addition of catalyst can be ignored. While under 30 min simulated sunlight, g-CNQDs, P25, H3PW12O40/TiO2, 5% g-CNQDs/TiO2, 10% g-CNQDs/H3PW12O40/TiO2, 3% g-CNQDs/H3PW12O40/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 exhibit degradation rates of 37.6%, 60.8%, 68.1%, 75.5%, 89.8%, 92.6% and 99.3% (Table 1), respectively. The photocatalytic performance of g-CNQDs/H3PW12O40/TiO2 composites exceeds that of g-CNQDs, P25, H3PW12O40/TiO2 and g-CNQDs/TiO2. The degree of photocatalytic activity enhancement by ternary hybrids varies with the doping amount of g-CNQDs, and 5% g-CNQDs/H3PW12O40/TiO2 displays the highest efficiency of 99.3% during photodegradation of RhB. The corresponding RhB degradation first-order kinetic curve (Fig. 6b) indicates that the reaction rate constants of g-CNQDs, P25, H3PW12O40/TiO2, 5% g-CNQDs/TiO2, 10% g-CNQDs/H3PW12O40/TiO2, 3% g-CNQDs/H3PW12O40/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 are 0.00927, 0.01863, 0.02243, 0.03036, 0.05291, 0.06363 and 0.10639 min−1 (Table 1), respectively. The degradation rate of 5% g-CNQDs/H3PW12O40/TiO2 is 11.48, 5.71, 4.74 and 3.51 times than that of g-CNQDs, P25, H3PW12O40/TiO2 and g-CNQDs/TiO2, respectively. It can be observed that the apparent rate constant of g-CNQDs/H3PW12O40/TiO2 hybrid materials is significantly higher than the sum of g-CNQDs and H3PW12O40/TiO2. This may be due to the fact that g-CNQDs are loaded into H3PW12O40/TiO2, which produces a heterojunction that inhibits photoelectron–hole recombination and improves photocatalytic performance. It is notable that too much or too little g-CNQDs loading will not optimize the catalytic effect of g-CNQDs/H3PW12O40/TiO2 ternary composite. When the doping amount of g-CNQDs is high, it is harmful to photocatalytic activity. This phenomenon may be due to the fact that excess g-CNQDs act as a light shield, resulting in decreased photocatalytic activity [45].
Finally, visible-light (400 nm < λ < 780 nm) photocatalytic activity of the TiO2-based materials was studied, and the result is shown in Fig. S4. As shown in Fig. S4a, the 5% g-CNQDs/H3PW12O40/TiO2 composite still exhibited the highest visible-light photocatalytic degradation efficiency. Under 75 min visible light, g-CNQDs, P25, H3PW12O40/TiO2, 5% g-CNQDs/TiO2, 10% g-CNQDs/H3PW12O40/TiO2, 3% g-CNQDs/H3PW12O40/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 displayed degradation rates of 36.4%, 51.2%, 58.7%, 70.2%, 93.6%, 98.5% and 99.2%, respectively. The apparent rate constant k (in Fig. S4b) over the g-CNQDs, P25, H3PW12O40/TiO2, 5% g-CNQDs/TiO2, 10% g-CNQDs/H3PW12O40/TiO2, 3% g-CNQDs/H3PW12O40/TiO2 and 5% g-CNQDs/H3PW12O40/TiO2 is 0.00631, 0.01097, 0.01506, 0.02185, 0.03591, 0.04818 and 0.06226 min−1, respectively. The degradation rate of 5% g-CNQDs/H3PW12O40/TiO2 was 9.86, 5.68, 4.13 and 2.85 times than that of g-CNQDs, P25, H3PW12O40/TiO2 and g-CNQDs/TiO2, respectively. Consequently, the introduction of g-CNQDs significantly boosts the photocatalytic activity of H3PW12O40/TiO2.
Considering the practical applications, it is necessary to evaluate the stability and recyclability of 5% g-CNQDs/H3PW12O40/TiO2 sample during photocatalytic reaction. Hence, five consecutive RhB degradation cycles of g-CNQDs/H3PW12O40/TiO2 composite are carried under simulated sunlight irradiation (Fig. 7). After each experiment, the photocatalysts were recovered by filtration, and washed three times with anhydrous ethanol and distilled water and dried at 80 °C for 12 h. In Fig. 7, the photocatalytic efficiency shows a trifling decline and there is no significant deactivation. The results confirmed that g-CNQDs/H3PW12O40/TiO2 can be regarded as a stable and effective heterogeneous photocatalyst in future applications.
In order to further prove the stability of the composites, TEM and XRD of g-CNQDs/H3PW12O40/TiO2 are studied after five cycles. As shown in Fig. S5, the TEM image of 5% g-CNQDs/H3PW12O40/TiO2 after 5 cycles is nearly the same as that of the original sample (Fig. 4c), which further demonstrates g-CNQDs/H3PW12O40/TiO2 is a stable recyclable photocatalyst. The XRD pattern of 5% g-CNQDs/H3PW12O40/TiO2 composites showed that the peak of g-CNQDs is very weak. In order to clearly observe the peak of g-CNQDs, XRD characterization is conducted for 10% g-CNQDs/H3PW12O40/TiO2 that after five cycles. As displayed in Fig. S6, the XRD pattern of the sample after five cycles is nearly the same with that of the initial sample, demonstrating that the crystalline structure of g-CNQDs/H3PW12O40/TiO2 is not changed during the photocatalytic reaction. The result is also consistent with the research of Yan et al. [49, 50].
Probable photocatalytic mechanism of g-CNQDs/H3PW12O40/TiO2
Photoelectrochemistry (PEC) measurements are taken to disclose the transfer and separation situation of light-excited charge carriers among composite materials [51]. As shown in Fig. 8a, the photocurrent–time (I–t) curves are obtained on a membrane which has four switching periods under intermittent Xe illumination. It can be observed that the addition of H3PW12O40 can enhance the photocurrent responses, whereas the photocurrent intensity of g-CNQDs/TiO2 is higher than that of H3PW12O40/TiO2. It shows that g-CNQDs have a notable effect on photocatalytic activity enhancement. Moreover, 5% g-CNQDs/H3PW12O40/TiO2 displays the strongest photocurrent responses, indicating more efficient separation of photoinduced e−–h+ pairs, which can be achieved by corresponding photoluminescence (PL) results for further demonstration. Under 280 nm laser illumination at room temperature, different catalytic samples show a broad PL peak centered at around 382 nm (Fig. 8b). The PL intensity obtained on g-CNQDs/H3PW12O40/TiO2 is much lower than that of TiO2, H3PW12O40/TiO2 and g-CNQDs/TiO2, which means that the lifetime of photogenerated carriers in 5% g-CNQDs/H3PW12O40/TiO2 is longer.
To study the detailed band potentials, the valence band XPS spectra and Mott–Schottky plots were analyzed to estimate the band positions of TiO2 and g-CNQDs, shown in Fig. S7. From Fig. S7a and b, it could be clearly seen that the flat band potentials of TiO2 and g-CNQDs were − 0.89 V and − 0.83 V versus Ag/AgCl, respectively. Using the Nernst equation [47], the flat band potentials of TiO2 and g-CNQDs were determined to be − 0.28 V and − 0.22 V versus NHE, respectively.
Moreover, as displayed in Fig. S7a and b, both slopes of the linear C−2 potential curves were positive, indicating that TiO2 and g-CNQDs were the n-type materials. Since the flat band potential was approximately equivalent to the Fermi level of the n-type material [48], the Fermi level of TiO2 was − 0.28 eV versus NHE and that of g-CNQDs was − 0.22 eV versus NHE. Furthermore, the valence band XPS spectra (Fig. S7c and d) revealed that the energy gaps between the valence band and the Fermi level were 3.16 eV and 1.84 eV for TiO2 and g-CNQDs, respectively. Therefore, the valence band (VB) position of TiO2 was calculated to equal to 2.88 eV. Combined with the bandgap value of TiO2 (3.06 eV) which was obtained from Fig. 5, the conduction band (CB) position of TiO2 was calculated as − 0.18 eV. Similarly, the CB position of g-CNQDs was calculated as − 1.11 eV.
In order to gain a deeper understanding of reaction mechanism, we studied the photoactive substances in the degradation process of organic contaminants over g-CNQDs/H3PW12O40/TiO2. The addition of ethylene diamine tetraacetic acid (EDTA), isopropanol (IPA) and 1,4-benzoquinone (BQ) plays the role of removing h+VB , ·OH and ·O2−, respectively. It can be seen from Fig. 9 that after 30 min of BQ and IPA addition, the removal efficiency of RhB decreases by 42.7% and 30.8%, respectively. However, the removal efficiency changes slightly after adding EDTA. It is speculated that the dominant active species in the photocatalytic process of g-CNQDs/H3PW12O40/TiO2 are ·O2− and ·OH, and the holes as an adjunct.
Discussion
Based on the results of photocatalytic experiments and trapping oxidants tests, a possible photocatalytic mechanism for the g-CNQDs/H3PW12O40/TiO2 is proposed and schematically exhibited in Scheme 1. Given the calculation results from XPS, the CB edge potentials for H3PW12O40, TiO2 and g-CNQDs are 0.22 eV, − 0.18 eV and − 1.11 eV, whereas those of VB are 3.70 eV, 2.88 eV and 1.62 eV, respectively. Under simulated sunlight irradiation, both g-CNQDs and TiO2 can be excited to generate electron–hole pairs because of the bandgap energy of g-CNQDs (2.73 eV) and TiO2 (3.06 eV). The CB edge of TiO2 is more negative than that of H3PW12O40; the photoinduced electrons on TiO2 to the CB of H3PW12O40, h+ remain on the VB of TiO2 and g-CNQDs. The e− on the CB of H3PW12O40 tends to recombine with the h+ on the VB of g-CNQDs. These transfers would diminish photoinduced carriers’ recombination and extend service life of charges. At the same time, e−CB that transferred onto the catalyst surface also reacted with oxygen molecules absorbed onto the catalyst surface to generate ·O2− and ·OH. Additionally, the h+ on VB of TiO2 could oxidize OH− or H2O to produce ·OH. Subsequently, the active species with strong oxidizing properties, including ·O2−, ·OH and h+VB , generated in the g-CNQDs/H3PW12O40/TiO2 photocatalytic system can bring the speedy transformation of organic dyes into inorganic compounds with the assistance of simulated sunlight. The detail response equations were shown from Eqs. (1) to (6).
It is apparent that the g-CNQDs/H3PW12O40/TiO2 ternary system exhibits enhanced photodegradation ability for the following reasons. Initially, the introduction of g-CNQDs can reduce bandgap energy and boost solar energy utilization of H3PW12O40/TiO2, which is easy to produce more h+VB and e−CB . Meanwhile, the up-conversion properties of g-CNQDs converts’ long-wave illumination light into shorter-wavelength emission light, which allows it to be further utilized in composite materials. Moreover, the increased specific surface area of g-CNQDs/H3PW12O40/TiO2 ternary material facilitates the adsorption of contaminants. Suitable band structure alignment and efficient electron transport among distinct photocatalysts are key factors in the formation of heterojunctions to boost electron transfer capability.
Conclusion
A new high-efficiency ternary composite photocatalyst g-CNQDs/H3PW12O40/TiO2 is obtained via coupling g-CNQDs with H3PW12O40/TiO2 by ultrasonic method. The results show that the g-CNQDs/H3PW12O40/TiO2 with 5% g-CNQDs loaded possesses the highest photocatalytic activity under simulated sunlight. The splendid photocatalytic performance probably originates from: (1) The matched bandgap position between the three materials effectively facilitates separation and migration of photogenerated electron–hole, thus enhancing the quantum efficiency. (2) The loading of g-CNQDs broadens the photoresponsive region of H3PW12O40/TiO2, and the up-conversion effect of g-CNQDs increases UV-light intensity, thereby increasing photon efficiency of the system. (3) The introduction of g-CNQDs raises the specific surface area of the ternary composite material and then increases the active sites of the reaction. (4) In the H3PW12O40/TiO2 reaction system, the active species are ·O2− and h+VB . For g-CNQDs/H3PW12O40/TiO2, the active species are not only ·O2− and h+VB but also ·OH, which is also the direct evidence of doping g-CNQDs to improve the degradation efficiency of pollutants. Studies have shown that g-CNQDs/H3PW12O40/TiO2 still has efficient photoactivity after five cycling runs and is considered as a potent and stable photocatalyst driven by sunlight.
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Acknowledgements
This work was financially supported by Science and Technology Development Plan of Jilin Province (20180520081JH) and Thirteen Five-Year Program for Science and Technology of Education Department of Jilin Province (JJKH20200803KJ, JJKH20200804KJ).
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Sun, T., Yu, X., Zhong, S. et al. Late-model g-CNQDs/H3PW12O40/TiO2 heterojunction nanocatalyst with enhanced photocatalytic performance. J Mater Sci 55, 15152–15166 (2020). https://doi.org/10.1007/s10853-020-05083-7
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DOI: https://doi.org/10.1007/s10853-020-05083-7