Background

Semiconductor photocatalysts have attracted increasing interest due to extenstive use in organic pollutant degradation and solar cells [1,2,3,4,5,6]. As the representative of semiconductor-based photocatalysts, TiO2 has been extensively investigated because of its excellent physical-chemical properties [7, 8]. However, the pure TiO2 photocatalyst has certain disadvantages in practical applications such as its wide band gap (3.2 eV for anatase and 3.0 eV for rutile), which leads to poor visible response.

A silver-based compound such as Ag2O, AgX (X = Cl, Br, I), Ag3PO4, Ag2CrO4, have been recently used for photocatalytic applications [9,10,11,12]. Among others, silver orthophosphate (Ag3PO4) has already attracted attention from many researchers because Ag3PO4 has a band gap of 2.45 eV and strong absorption at less than 520 nm. The quantum yield of Ag3PO4 is over 90%. It is a good visible-light photocatalyst. However, due to the formation of Ag0 on the surface of the catalyst (4Ag3PO4 + 6H2O + 12h+ + 12e → 12Ag0 + 4H3PO4 + 3O2) during the photocatalytic reaction, the reuse of Ag3PO4 is a major problem. Therefore, it is a common practice to reduce photocatalytic corrosion of Ag3PO4 and ensure good catalytic activity of Ag3PO4. Based on literature precedence, it is known that compounding can effectively improve the photocatalytic performance of both semiconductor materials. After compounding, the separation effect of photogenerated electrons and holes is strengthened, contributing to enhance the photocatalytic activity of composite materials. Numerous researchers have investigated heterojunctions such as Bi2O3-Bi2WO6, TiO2/Bi2WO6, ZnO/CdSe, and Ag3PO4/TiO2 [2, 13,14,15]. Compared with single-phase photocatalysts, heterojunction photocatalysts can expand the light response range by coupling matched electronic structure materials. And because of the synergistic effect between components, charge can be transferred through many ways to further improve heterojunction photocatalytic activity.

Based on the above analysis, Ag3PO4-based semiconductor composites with synergistic enhancement effect were designed to improve carrier recombination defects and Ag3PO4-based semiconductor composites catalytic performance. In this paper, nano-sized TiO2 was prepared by solvothermal method, and then the nanoparticles of TiO2400 were deposited on the surface of Ag3PO4 at room temperature to obtain TiO2/Ag3PO4 composites. The photocatalytic activity of TiO2/Ag3PO4 composite was tested using RhB dye (rhodamine B).

Methods

Hydrothermal Preparation of Nano-sized TiO2

0.4 g P123 was added to a mixed solution containing 7.6 mL absolute ethanol and 0.5 mL deionized water and stirred until P123 was completely dissolved. The clarified solution was labeled as A solution. Then a mixed solution containing 2.5 mL butyl titanate (TBOT) and 1.4 mL concentrated hydrochloric acid (12 mol/L) was prepared and labeled as B solution. The solution B was added to solution A by drop. After stirring for 30 min, 32 mL ethylene glycol (EG) was added to the solution and stirred for 30 min. Then, the solution was placed in oven, at 140 °C, high temperature, and high pressure for 24 h. Natural cooling, centrifugal washing, separation, collection of sediments, and drying at 80 °C oven for 8 h. The white precipitation was calcined in muffle furnace at different temperatures (300 °C, 400 °C, 500 °C) and marked as standby of TiO2300, TiO2400, and TiO2500, respectively.

Preparation of TiO2/Ag3PO4 Photocatalyst

The 0.1 g TiO2 powder was added to the 30-mL silver nitrate solution containing 0.612 g AgNO3 and then treated by ultrasound for 30 min to make TiO2 dispersed uniformly. We added 30-mL solution containing 0.43 g Na2HPO4.12H2O and stirred for 120 min at ambient temperature. By centrifugation, cleaning with deionized water and anhydrous ethanol, the precipitates were separated, collected, and dried at 60 °C. The products were named as TiO2300/Ag3PO4, TiO2400/Ag3PO4, and TiO2500/Ag3PO4, respectively. Ag3PO4 was prepared without adding TiO2 under the same conditions as the above process.

Characterization

The X-ray diffraction (XRD) patterns of the resulted samples were performed on a D/MaxRB X-ray diffractometer (Japan), which has a 35 kV Cu-Ka with a scanning rate of 0.02° s−1, ranging from 10 to 80°. Scanning electron microscopy (SEM), JEOL, JSM-6510, and JSM-2100 transmission electron microscopy (TEM) assembly with energy dispersive X-ray spectroscopy (EDX) were used to study its morphology at 10-kV acceleration voltage. X-ray photoelectron spectroscopy (XPS) information were collected by using an ESCALAB 250 electron spectrometer under 300-W Cu Kα radiation. The basic pressure was about 3 × 10−9 mbar, Combine to refer to the C1s line at amorphous carbon 284.6 eV.

Photocatalytic Activity Measure

The photocatalytic performance of TiO2/Ag3PO4 catalysts was tested by using the photodegradation of RhB in aqueous solution as the research object. Fifty milligrams of the photocatalyst was mixed with 50 mL of RhB aqueous solution (10 mg L−1) and stirred in darkness for a certain time before illumination to ensure adsorption balance. In the reaction process, cooling water is used to keep the system temperature constant at room temperature. A 1000-W Xenon lamp provides illumination to simulate visible light. LAMBDA35 UV/Vis spectrophotometer was used to characterize the concentration (C) change of RhB solution at λ = 553 nm. The decolorization rate is indicated as a function of time vs Ct/C0. Where C0 is the concentration before illumination, and Ct is the concentration after illumination. Used catalysts were recollected to detect the cycle stability of the catalysts. The experiment was repeated four times.

Results and Discussion

XRD analysis is used to determine the phase structure and crystalline type of catalyst. The XRD spectra of the prepared catalysts were shown in Fig. 1, including TiO2400, Ag3PO4, TiO2/Ag3PO4, TiO2300/Ag3PO4, TiO2400/Ag3PO4, and TiO2500/Ag3PO4. It can be obtained from the figure that the crystal structure of TiO2400 is anatase (JCPDS No. 71-1166). In the XRD spectra of Ag3PO4, the diffraction peaks located at 20.9°, 29.7°, 33.3°, 36.6°, 47.9°, 52.7°, 55.1°, 57.4°, 61.7°, and 72.0° belong to the characteristic peaks of (110), (200), (210), (211), (310), (222), (320), (321), (400), and (421) planes of Ag3PO4 (JCPDS No. 70-0702), respectively. The synthesized composite photocatalysts showed characteristic peaks consistent with TiO2 and Ag3PO4, and the characteristic peaks of TiO2 were 25.3° at the composite TiO2, TiO2300/Ag3PO4, TiO2400/Ag3PO4, TiO2500/Ag3PO4, which was consistent with the calcination temperature of TiO2 rise, the crystallinity of TiO2 becomes higher.

Fig. 1
figure 1

The XRD patterns of the as-prepared samples

Figure 2 shows the SEM, TEM, and EDX diagrams of the catalysts of TiO2400, Ag3PO4, and TiO2400/Ag3PO4. Figure 2a is the spherical nanostructure TiO2400 prepared by solvothermal method with a diameter ranging from 100 to 300 nm. Figure 2b is the Ag3PO4 crystal with a regular hexahedral structure. Its particle size ranges from 0.1 to 1.5 μm and has a fairly smooth surface. Figure 2c is the SEM image of the composite TiO2400/Ag3PO4. It can be seen that the nanoparticles of TiO2400 are deposited on the surface of Ag3PO4. The morphology of TiO2400/Ag3PO4 was further explored with TEM and the TEM diagram of TiO2400/Ag3PO4 is displayed in Fig. 2d. It can be observed that 200-nm nano-sized TiO2 particles adhere to the surface of Ag3PO4. Figure 2e is the HRTEM of TiO2400/Ag3PO4. It can be founded that TiO2 particles are closely bound to Ag3PO4, and the lattice spacing of TiO2400 and Ag3PO4 are 0.3516 and 0.245 nm, respectively, corresponding to (101) and (211) surfaces of TiO2 and Ag3PO4. Figure 2f is the EDX diagram of TiO2400/Ag3PO4. It can be seen that the sample consists of four elements: Ti, O, Ag, and P. The obvious diffraction peak of copper element is produced by the EDX excitation source, Cu Ka. EDX confirmed the corresponding chemical elements of TiO2400/Ag3PO4. In conclusion, it can be clearly judged that TiO2 is loaded on the surface of Ag3PO4 crystals in granular form and has a good hexahedron morphology.

Fig. 2
figure 2

SEM images of prepared photocatalysts: a TiO2400, b Ag3PO4, c TiO2400/Ag3PO4, d TEM image of TiO2400/Ag3PO4, e HRTEM image of TiO2400/Ag3PO4, and f corresponding EDX pattern of TiO2400/Ag3PO4

The product X-ray photoelectron spectroscopy (XPS) is investigated in Fig. 3. Figure 3a is the survey XPS spectrum of the product. Ti, O, Ag, P, and C five elements can be observed in the graph, of which C is the base, implying that composite coexisted with TiO2 and Ag3PO4. Figure 3b is the high-resolution spectrum of Ag 3d. The two main peaks centered at binding energy 366.26 eV and 372.29 eV, assigning to Ag 3d5/2 and Ag 3d3/2, respectively. It shows that Ag is mainly Ag+ in the photocatalyst of TiO2400/Ag3PO4 [16]. Figure 3c shows the XPS peak of P 2p, which corresponds to P5+ in the PO43+ structure at 131.62 eV. Two peaks located at 457.43 eV and 464.58 eV can be attributed to Ti 2p3/2 and Ti 2p1/2 in the XPS spectrum of Ti 2p orbital (Fig. 3d). Figure 3e is the XPS of O 1s. The whole peak can be divided into three characteristic peaks, 528.9 eV, 530.2 eV, and 532.1 eV. The peaks at 528.9 eV and 530.2 eV are ascribed to oxygen in Ag3PO4 and TiO2 lattices, respectively. The peaks at 532.1 eV indicate hydroxyls or the oxygen adsorbed on the surface of TiO2/Ag3PO4. The results of XPS analysis further prove that Ag3PO4 and TiO2 have been compounded.

Fig. 3
figure 3

XPS spectrum of TiO2400/Ag3PO4: a survery scan, b Ag 3d, c P 2p, d Ti 2p, and e O1s

The UV-Vis diffuse reflectance absorption spectra of the catalysts of TiO2400, Ag3PO4, and TiO2400/Ag3PO4 are exhibited in Fig. 4a. It can be seen from the figure that the optical absorption cutoff wavelengths of TiO2400 and Ag3PO4 are 400 and 500 nm, respectively. When Ag3PO4 is loaded on TiO2400, the light absorption range of the composite obviously broadens to 500–700 nm, indicating that there is interaction between Ag3PO4 and TiO2400 in the composite system of TiO2400/Ag3PO4, and the mechanism needs further study. Bandwidth of Ag3PO4, TiO2400, and TiO2400/Ag3PO4 catalysts is computed with the Kubelka-Munk formula [17]:

$$ A\mathrm{hv}=c{\left(\mathrm{hv}-\mathrm{Eg}\right)}^n $$
Fig. 4
figure 4

TiO2400, Ag3PO4, and TiO2400/Ag3PO4 catalysts: a UV-Vis DRS, b plots of (αhv)1/2 versus energy (hv)

where A, hv, c, and Eg are the absorption coefficient, incident photon energy, absorption constant, and band gap energy, respectively. The value of n for direct semiconductor is 1/2, and that for indirect semiconductor is 2. Anatase TiO2 and Ag3PO4 are indirect semiconductors, so n takes 2.

The plots depicting (αhv)1/2 versus incident photon energy (hv) from Fig. 4b indicates the band gap energy diagrams (Eg) of Ag3PO4, TiO2400, and TiO2400/Ag3PO4 catalysts are 2.45 eV, 3.1 eV, and 2.75 eV, respectively. This further proves that TiO2400/Ag3PO4 is a good visible-light photocatalyst with suitable band gap width and visible light capture ability.

Photocatalytic degradation of RhB by TiO2400, Ag3PO4, TiO2300/Ag3PO4, TiO2400/Ag3PO4, and TiO2500/Ag3PO4 was investigated in Fig. 5a. The results showed that pure TiO2400 had the worst photocatalytic effect, and the photocatalytic degradation rate was only 30% within 25 min. The photocatalytic degradation efficiency of pure Ag3PO4 was 69% after 25 min of irradiation. The photocatalytic degradation rate of TiO2300/Ag3PO4 reached 40% after 25 min. The photocatalytic degradation rate of TiO2500/Ag3PO4 was 80% after 25 min of irradiation. The best photocatalytic activity was TiO2400/Ag3PO4, and 100% of RhB was decomposed after 25 min of illumination.

Fig. 5
figure 5

a Effects of different catalysts on photocatalytic degradation of RhB under visible light. b First order kinetic fitting plots of photocatalytic degradation of RhB with different catalysts. c Cycling runs of TiO2400/Ag3PO4. d Trapping experiments of active species

Figure 5b studied the kinetics model of photocatalytic degradation of RhB. From the figure, the photodegradation of RhB was followed pseudo-first-order kinetics and the reaction rate constant (k) was calculated with the slope of fitting curves. The reaction rate constant (k) values of each sample were shown in Table 1. The reaction rate constants of TiO2400, Ag3PO4, TiO2300/Ag3PO4, TiO2400/Ag3PO4, and TiO2500/Ag3PO4 were 0.00345 min−1, 0.01148 min−1, 0.00525 min−1, 0.02286 min−1, and 0.01513 min−1, respectively. The sample TiO2400/Ag3PO4 has the largest reaction rate constant, which is 0.02286 min−1, twice that of Ag3PO4 and 6.6 times that of the minimum value of TiO2400. This indicates that the combination of Ag3PO4 and TiO2 can greatly contribute to the improvement of Ag3PO4 photocatalytic activity.

Table 1 Photo degradation rate constants and linear regression coefficients of different catalysts from equation − ln(C/C0) = kt.

Figure 5c is the stability test result of four times of degradation of RhB solution by recycling of TiO2400/Ag3PO4. The degradation effect of TiO2400/Ag3PO4 shows good stability in four times of recycling, and in the fourth cycle experiment, the degradation effect of TiO2400/Ag3PO4 was slightly higher than that of the third cycle. This may be due to the formation of composite material between Ag3PO4 and TiO2 to accelerate photogenerated electron-hole pair transfer and in situ formation of a small amount of Ag in Ag3PO4 during photocatalysis to inhibit further photo-corrosion.

The results of TiO2/Ag3PO4 capture factors are shown in Fig. 5d. After the addition of trapping agent IPA, the degradation activity decreased partially. When BQ and TEOA were added, the degradation degree of RhB decreased significantly, even close to 0. Therefore, we can infer that the main factors are holes (h+) and superoxide anions (O·− 2), while hydroxyl radical (·OH) plays partially degradation.

A possible Z-scheme photocatalytic degradation mechanism was proposed in Scheme 1 to expatiate the photocatalytic degradation of RhB by TiO2/Ag3PO4 based on free radical capture and photodegradation experiments. The band gap of Ag3PO4 is 2.45 eV, and its ECB and EVB potential are ca.0.45 eV and 2.9 eV (vs. NHE) [18], respectively. As shown in Scheme 1, under visible light irradiation, Ag3PO4 is stimulated by photons with energy greater than its band gap to produce photogenerated electron-hole pairs. The holes left in the valence band of Ag3PO4 migrated to the valence band of TiO2 and then directly participated in the RhB oxidation and decomposition process, which adsorbed on the surface of TiO2. At the same time, during the migration of photogenerated holes, the H2O and OH adsorbed on the composite surface can also be oxidized to form ·OH, and the highly oxidizing ·OH can further oxidize and degrade pollutants. This is mainly due to the energy of holes in the valence band of Ag3PO4 which is 2.9 eV, higher than the reaction potential energy of OH/OH (E(OH/OH) = 1.99 eV (vs. NHE)). However, the conduction potential of Ag3PO4 is 0.45 eV, the energy of photogenerated electrons is 0.45 eV, and the activation energy of single electron oxygen is E(O2/O·− 2) = 0.13 eV (vs. NHE). The photogenerated electrons on Ag3PO4 conduction band cannot be captured by dissolved oxygen. With the accumulation of photogenerated electrons on Ag3PO4 conductive band, a small amount of Ag nanoparticles has been formed due to the photocatalytic corrosion of Ag3PO4 photocatalyst. The formed Ag nanoparticles can also be stimulated by light energy to form photogenerated electron-hole pairs. Then the electrons migrated to the conduction band of TiO2, while the holes left on the Ag nanoparticles can be compounded with the photogenerated electrons generated on the conduction band of Ag3PO4, thus preventing the further corrosion of Ag3PO4 photocatalyst. Due to the forbidden band of TiO2 is 3.1 eV, it cannot be excited under visible light and the ECB and EVB are ca. − 0.24 eV and 2.86 eV (vs. NHE), respectively. Electrons injected into TiO2 conduction band can degrade pollutants through trapping the oxygen adsorbed onto the TiO2 surface. This is mainly due to the ECB = − 0.24 eV (vs. NHE) which is more negative than E(O2/O·- 2) = 0.13 eV (vs. NHE). The results are in accordance with the trapping experiments. The main factors are holes (h+) and superoxide anions (O·- 2), while hydroxyl radical (·OH) plays partially degradation.

Scheme 1
scheme 1

Schematic illustration of the photocatalytic mechanism of TiO2/Ag3PO4

Basing on the above discussion, the degradation reaction of TiO2/Ag3PO4 is expressed by the chemical equation as follows:

Generation of photoelectron hole pairs:

$$ {\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4+\mathrm{hv}\to {\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4\left({\mathrm{e}}^{-}\right)+{\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4\left({\mathrm{h}}^{+}\right) $$
$$ {\mathrm{Ag}}^{+}+{\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4\left({\mathrm{e}}^{-}\right)\to \mathrm{Ag}+{\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4 $$
$$ \mathrm{Ag}+\mathrm{hv}\to \mathrm{Ag}\left({\mathrm{e}}^{-}\right)+\mathrm{Ag}\left({\mathrm{h}}^{+}\right) $$

Migration and transformation of photogenerated hole electron pairs:

$$ {\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4\left({\mathrm{h}}^{+}\right)+\mathrm{Ti}{\mathrm{O}}_2\to \mathrm{Ti}{\mathrm{O}}_2\left({\mathrm{h}}^{+}\right)+{\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4 $$
$$ {\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4\left({\mathrm{e}}^{-}\right)+\mathrm{Ag}\left({\mathrm{h}}^{+}\right)\to \mathrm{Ag}+{\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4 $$
$$ \mathrm{Ag}\left({\mathrm{e}}^{-}\right)+\mathrm{Ti}{\mathrm{O}}_2\to \mathrm{Ti}{\mathrm{O}}_2\left({\mathrm{e}}^{-}\right)+\mathrm{Ag} $$
$$ \mathrm{Ti}{\mathrm{O}}_2\left({\mathrm{e}}^{-}\right)+{\mathrm{O}}_2\to {\mathrm{O}}_2^{\cdotp -}+\mathrm{Ti}{\mathrm{O}}_2 $$
$$ {\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4\left({\mathrm{h}}^{+}\right)+0{\mathrm{H}}^{-}\to \mathrm{OH}\cdotp +{\mathrm{Ag}}_3\mathrm{P}{\mathrm{O}}_4 $$

Degradation of pollutants:

$$ \mathrm{Ti}{\mathrm{O}}_2\left({\mathrm{h}}^{+}\right)+\mathrm{RhB}\to \mathrm{Degradation}\ \mathrm{product}+{\mathrm{CO}}_2+{\mathrm{H}}_2\ \mathrm{O} $$
$$ {\mathrm{O}}_2^{\cdotp -}+\mathrm{RhB}\to \mathrm{Degradation}\ \mathrm{product}+{\mathrm{CO}}_2+{\mathrm{H}}_2\ \mathrm{O} $$
$$ \mathrm{OH}\cdotp +\mathrm{RhB}\to \mathrm{Degradation}\ \mathrm{product}+{\mathrm{CO}}_2+{\mathrm{H}}_2\ \mathrm{O}+{\mathrm{Cl}}^{-} $$

Conclusions

In summary, a comprehensive investigation of the composite Ag3PO4/TiO2 photocatalyst, prepared by a simple two-step method is presented. Complementary characterization tools such as X-ray diffraction (XRD), scanning electron microscopy (SEM), transmission electron microscopy (TEM), high-resolution transmission electron microscopy (HR-TEM), energy dispersive X-ray spectroscopy (EDX), X-ray photoelectron spectroscopy (XPS), and UV-vis diffuse reflectance spectroscopy (DRS) were utilized in this study. The results showed that the composite Ag3PO4/TiO2 photocatalyst is highly crystalline and has good morphology. For Ag3PO4/TiO2 degradation of RhB, TiO2400/Ag3PO4 shows the highest photocatalytic activity. After 25 min of reaction, the photocatalytic degradation rate reached almost 100%. The reaction rate constant of TiO2400/Ag3PO4 is 0.02286 min−1, which is twice that of Ag3PO4 and 6.6 times that of the minimum value of TiO2400. The TiO2400/Ag3PO4 also exhibits good stability after recycling four times. The main active catalytic species are holes (h+) and superoxide anions (O·− 2), while hydroxyl radical (·OH) plays partially degradation from trapping experiments. In addition, a Z-scheme reaction mechanism of Ag3PO4/TiO2 heterogeneous structure is proposed to explain the RhB degradation mechanism. The accumulation of photogenerated electrons on Ag3PO4 conductive band causes photoetching of Ag3PO4 photocatalyst to form a small amount of Ag nanoparticles, consequently, accelerating photogenerated electron transfer in the Ag3PO4 conduction band, thus preventing further Ag3PO4 photocatalyst corrosion.