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Sliver Doped Sodium Antimonate with Greatly Reduced the Band Gap for Efficiently Enhanced Photocatalytic Activities Under Visible Light (Experiment and DFT Calculation)

Abstract

In this work, Ag doped NaSbO3 (ANS) was successfully synthesized and applied an efficient visible light photocatalyst. The properties of catalyst were fully characterized, and DFT (the density functional theory) computation was utilized to investigate the photocatalytic mechanism. The various characterization findings proved that Ag atoms were perfectly doped into NaSbO3 crystals, which greatly reduced the band gap, and made ANS catalyst exhibit excellent visible light absorption performance. In addition, ANS appeared great photocatalytic activities and remarkable stability. Also, electrochemical characterizations illustrated that ANS possessed stronger ability of generating and transferring electrons and holes under visible light, and the doping of Ag atoms reduced the resistance of charge transfer, thus effectively accelerated the photocatalysis reaction. Moreover, through ESR characterization and scavengers coexistent experiments, •OH and •O2- were considered to be active radicals that played a crucial role in the photodegradation process. Furthermore, DFT calculation demonstrated that ANS displayed obvious visible light excitation performance via reducing the band gap. The improvement of work function enhanced the oxidation ability of photogenerated holes, forming more hydroxyl radicals, thus boosted the photodegradation of pollutants.

Keywords:
Sliver Doping; Sodium Antimonate; Photocatalyst; Band gap; DFT computation

1. Introduction

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According to the classical theory of energy bands in solid, there are valence bands and conduction bands in electron energy bands1818 Wang Q, Gao Q, Al-Enizi AM, Nafady A, Ma S. Recent advances in MOF-based photocatalysis: environmental remediation under visible light. Inorg Chem Front. 2020;7(2):300-39.,1919 Rueda-Marquez JJ, Levchuk I, Ibanez PF, Sillanpaa M. A critical review on application of photocatalysis for toxicity reduction of real wastewaters. J Clean Prod. 2020;258:120694.. The energy difference between the valence band top and the conduction band bottom is called band gap. When the band gap is ranged from 1.5eV to 3.0eV, the material will have obvious visible light absorption properties2020 Yong X, Schooneb MAA. The absolute energy positions of conduction and valence bands of selected semiconducting minerals. Am Mineral. 2000;85:543-56.,2121 Zhang M, Yang Y, An X, Hou L-a. A critical review of g-C3N4-based photocatalytic membrane for water purification. Chem Eng J. 2021;412:128663.. When a solid with suitable band gap absorbs visible light, electrons in the valence band can be excited to the conduction band to form photogenic electrons and photonic holes in the valence band. After these photogenerated electrons and photogenerated holes diffuse to the solid surface, they can not only directly oxidize and reduce efficiently with pollutants, but also react with oxygen and hydroxyl radicals in system to form highly active superoxide radicals and hydroxyl radicals, and further decompose pollutants2222 Wang X, Hu C, An H, Zhu D, Zhong Y, Wang D, et al. Photocatalytic removal of MB and hydrogen evolution in water by (Sr0.6Bi0.305)2Bi2O7/TiO2 heterostructures under visible-light irradiation. Appl Surf Sci. 2021;544:148920.,2323 Zhang Y, Zhou J, Feng Q, Chen X, Hu Z. Visible light photocatalytic degradation of MB using UiO-66/g-C3N4 heterojunction nanocatalyst. Chemosphere. 2018;212:523-32..

At present, the main catalysts for photocatalytic reactions under visible light include ZnO2424 Somraksa W, Suwanboon S, Amornpitoksuk P, Randorn C. Physical and photocatalytic properties of CeO2/ZnO/ZnAl2O4 ternary nanocomposite prepared by co-precipitation method. Mater Res. 2020;23(1):1-10.,2525 Sun L, Shao Q, Zhang Y, Jiang H, Ge S, Lou S, et al. N self-doped ZnO derived from microwave hydrothermal synthesized zeolitic imidazolate framework-8 toward enhanced photocatalytic degradation of methylene blue. J Colloid Interface Sci. 2020;565:142-55., BiVO42626 Tang S, Wang Z, Yuan D, Zhang Y, Qi J, Rao Y, et al. Enhanced photocatalytic performance of BiVO4 for degradation of methylene blue under LED visible light irradiation assisted by peroxymonosulfate. Int J Electrochem Sci. 2020;15(3):2470-80.,2727 Wang Y, Ding K, Xu R, Yu D, Wang W, Gao P, et al. Fabrication of BiVO4/BiPO4/GO composite photocatalytic material for the visible light-driven degradation. 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Int J Hydrogen Energy. 2020;45(28):14354-67., Ag3PO43232 Tang M, Ao Y, Wang C, Wang P. Facile synthesis of dual Z-scheme g-C3N4/Ag3PO4/AgI composite photocatalysts with enhanced performance for the degradation of a typical neonicotinoid pesticide. Appl Catal B. 2020;268:118395.,3333 Shao B, Liu X, Liu Z, Zeng G, Liang Q, Liang C, et al. A novel double Z-scheme photocatalyst Ag3PO4/Bi2S3/Bi2O3 with enhanced visible-light photocatalytic performance for antibiotic degradation. Chem Eng J. 2019;368:730-45., AgBr3434 He Y, Zeng L, Feng Z, Zhang Q, Zhao X, Ge S, et al. Preparation, characterization, and photocatalytic activity of novel AgBr/ZIF-8 composites for water purification. Adv Powder Technol. 2020;31(1):439-47. and so forth. Sb element related materials including BiSbO4/BiOBr nanoarchitecture3535 Wang Z, Wang K, Li Y, Jiang L, Zhang G. Novel BiSbO4/BiOBr nanoarchitecture with enhanced visible-light driven photocatalytic performance: oxygen-induced pathway of activation and mechanism unveiling. Appl Surf Sci. 2019;498:143850., AgI/BiSbO4 heterojunction3636 Wang Z, Jiang L, Wang K, Li Y, Zhang G. Novel AgI/BiSbO4 heterojunction for efficient photocatalytic degradation of organic pollutants under visible light: interfacial electron transfer pathway, DFT calculation and degradation mechanism study. J Hazard Mater. 2021;410:124948. and carbon dots modified BiSbO4 composites3737 Wang Z, Cheng Q, Wang X, Li J, Li W, Li Y, et al. Carbon dots modified bismuth antimonate for broad spectrum photocatalytic degradation of organic pollutants: boosted charge separation, DFT calculations and mechanism unveiling. Chem Eng J. 2021;418:129460. have attracted much attention in the field of photocatalysis. During Sb related materials, NaSbO3 is a common industrial raw material, which can be used as opaque filler, enamel whitening agent, iron sheet, and acid resistant paint of steel plate, etc. It can be also used as a raw material for the synthesis of AgSbO33838 Chen DP, Bowers W, Skrabalak SE. Aerosol-assisted combustion synthesis of single-crystalline NaSbO3 nanoplates: a topotactic template for ilmenite AgSbO3. Chem Mater. 2015;27(1):174-80.,3939 Ashok J, Brik MG, Kumar VR, Veeraiah N. Energy band structure and optical band gap calculations of AgSbO3 photo-catalystic pyrochlore crystal phase embedded in Ag2O doped sodium antimonate glass ceramics. Optik. 2020;206:164345.. In addition, NaSbO3 itself displays certain photosensitivity. However, because its band gap is as high as about 4.5eV, so only ultraviolet light can excite electrons in its valence band to the conduction band. This greatly limits the application of NaSbO3 in the field of photocatalysis4040 Singh J, Uma S. Efficient photocatalytic degradation of organic compounds by ilmenite AgSbO3 under visible and UV light irradiation. J Phys Chem C. 2009;113(28):12483-8.,4141 Laurita G, Page K, Sleight AW, Subramanian MA. Structural investigation of the substituted pyrochlore AgSbO3 through total scattering techniques. Inorg Chem. 2013;52(19):11530-7.. Theoretically speaking, each photocatalyst has its own specific electron energy band. However, due to its limited light absorption and critical problems of photogenerated holes recombination caused by poor charge separation, the reducing capability of a single semiconductor photocatalytic material are relatively limited. In this situation, many researchers have focused their efforts on various composite photocatalytic materials, to address these issues and thus accelerate the photocatalytic activities, and then enhance the photocatalytic degradation efficiencies4242 Mao S, Shi J, Sun G, Ma D, He C, Pu Z, et al. Au nanodots@thiol-UiO66@ZnIn2S4 nanosheets with significantly enhanced visible-light photocatalytic H2 evolution: the effect of different Au positions on the transfer of electron-hole pairs. Appl Catal B. 2021;282:119550.,4343 Wang K, Xing Z, Meng D, Zhang S, Li Z, Pan K, et al. Hollow MoSe2@Bi2S3/CdS Core-Shell nanostructure as dual Z-Scheme heterojunctions with enhanced full spectrum photocatalytic-photothermal performance. Appl Catal B. 2021;281:119482.. According to the theory of semiconductor physics, impurity doping is an effective method to decrease the band gap of semiconductor materials4444 Onkani SP, Diagboya PN, Mtunzi FM, Klink MJ, Olu-Owolabi BI, Pakade V. Comparative study of the photocatalytic degradation of 2-chlorophenol under UV irradiation using pristine and Ag-doped species of TiO2, ZnO and ZnS photocatalysts. J Environ Manage. 2020;260:110145.,4545 Ismael M. Enhanced photocatalytic hydrogen production and degradation of organic pollutants from Fe (III) doped TiO2 nanoparticles. J Environ Chem Eng. 2020;8(2):103676.. Appropriate impurity doping could add additional energy levels between the valence band and conduction band of raw material, effectively reduce the band gap of semiconductor, and make it excited under visible light, thus improve the photocatalytic degradation performance2525 Sun L, Shao Q, Zhang Y, Jiang H, Ge S, Lou S, et al. N self-doped ZnO derived from microwave hydrothermal synthesized zeolitic imidazolate framework-8 toward enhanced photocatalytic degradation of methylene blue. J Colloid Interface Sci. 2020;565:142-55.,4646 Qi K, Xing X, Zada A, Li M, Wang Q, Liu S-y, et al. Transition metal doped ZnO nanoparticles with enhanced photocatalytic and antibacterial performances: experimental and DFT studies. Ceram Int. 2020;46(2):1494-502.. If composite photocatalysts can decrease the band gap through the doping, then enhancement of photocatalytic performance is expected.

In this work, the Ag atom was successfully doped into NaSbO3 crystals by hydrothermal ion exchange reaction, and prepared Ag doped NaSbO3 visible light photocatalytic material (ANS). Our research firstly demonstrated that simple doping of photocatalyst could highly reduce the band gap of material, making photocatalyst exhibit excellent absorption performance under visible light, and enhancing the oxidation ability of photogenerated holes. The various properties of catalyst were fully characterized by modern analytical instruments, including its chemical composition, morphology, doping structure, optical absorption, and so forth. Also, the photodegradation mechanism of ANS catalyst was illustrated with the aid of a series of electrochemical tests. Moreover, the VASP software and DFT calculation was conducted to further investigate the action of photogenerated holes, and deeply clarify the photocatalytic mechanism. Besides, the photocatalytic efficiency of ANS was evaluated by photodegradation experiments of Methylene Blue (MB) in solution. Additionally, to clarify the reaction processes, the impact factors, including catalyst dosage, reaction time, reaction kinetics, trapping agents, and recycle performance were studied. Furthermore, this technique is highly useful in designing more capable photocatalysts for various applications in the photodegradation of organic pollutants.

2. Experiments and Methods

2.1. Synthesis of photocatalyst

The synthesis steps of photocatalyst were as follows: Firstly, 0.0035mol of NaSbO3·3H2O and 0.0010mol to 0.0035mol of AgNO3 were weighed, respectively. NaSbO3·3H2O was added into 60ml deionized water to form a milky white hydrosol system. Secondly, AgNO3 was gradually added into the mixture while stirred with magnetic force. Thirdly, the mixture was stirred at the temperature of 55°C for 90 minutes to form a coffee color hydrosol system. Fourthly, this mixture was transferred to a stainless steel reactor on a teflon substrate for hydrothermal reaction for 9 hours at 90°C. After the reaction was completed, the reaction product was then cooled to room temperature (the air conditioning in laboratory was set at 25°C), filtered, washed with deionized water for several times until its neutral. After that, the reaction product was dried at 75°C in the blast drying oven. Finally, the synthetic product was grounded into finer particles with an agate mortar, and the photocatalyst was obtained. The schematic illustration of the synthesis process was depicted in Figure 1.

Figure 1
The schematic illustration of the synthesis process.

Figure 2 depicted the effect of the molar ratio of AgNO3 and NaSbO3 on the removal rate of MB (30 minutes) during the synthesis process. As the molar ratio increased, the degradation effect of MB was gradually improved. However, when the molar ratio increased to 0.57, the degradation effect of MB was no longer obvious. Therefore, considering the cost of the ANS catalyst, it was believed that the molar ratio of 0.57 was more economical.

Figure 2
The effect of mole ratio (AgNO3/NaSbO3) in synthesis process on the removal rate of MB.

2.2. Materials characterization

To illustrate the various properties of material synthesized, samples were fully characterized by Scanning electron microscopy-energy dispersive spectroscopy (SEM-EDX), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), UV-vis diffuse reflectance spectra, photoluminescence (PL), Electron spin resonance (ESR), electrochemical impedance spectroscopy (EIS), electrochemical photocurrent (interval 20s), and other advanced instruments. The Liquid specific surface area of ANS Catalyst was analyzed through Xigo Liquid specific surface area Determinator. The particle size distribution was analyzed by Malvern Mastersizer 2000 Laser particle size analyzer. The morphologies of material were examined with a HITACHI(S-3400N) scanning electron microscope. XRD patterns of powder samples were recorded by a Shimadzu XD-3A diffractometer, employing Cu-Kα radiation (λ = 1.54056Å). The X-ray photoelectron spectroscopy spectra were examined by a PHI 5000 VersaProbe XPS equipment. The UV-vis spectra were conducted by PerkinElmer Ultraviolet spectrophotometer. The solid photoluminescence was conducted by HITACHI Fluorescence spectrometer (F-7000). The Electron spin resonance was examined by Electron paramagnetic resonance spectrometer (EMXmicro-6/1/P/L, Karlsruhe, Germany utilizing). The DMPO (5, 5-dimethyl-1-pyrroline N -oxide) was used as free radical (•O2- and •OH) trapping agent. The electrochemical impedance spectroscopy and photocurrent (interval 20s) was measured on a CHI 660E electrochemical workstation.

2.3. Photocatalytic experiments of ANS

Photocatalytic experiments were conducted through degradation of methylene blue under visible light irradiation (300W Xe-lamp). During each experiment, the photocatalyst (from 0.005g to 0.030g) was added into 30ml MB solution (the initial concentration was 10mg/L). All photocatalytic experiments were conducted at room temperature (the air conditioning in laboratory was set at 25°C), and the mixtures were put into a transparent photoreaction vessel. In addition, the photocatalytic reaction time ranged from 0 to 30minutes. After the reaction, the concentration of MB was determined by Ultraviolet visible spectrophotometer at 662nm.

To estimate the photodegradation performance of recycled sample, the consecutive cycles were done to measure the photocatalytic efficiencies of MB. At the same time, the morphology and XRD patterns of recycled ANS were also investigated. After each recycled cycle, the catalyst was filtered out from the solution by 0.45μm filter membrane, and the filer solids were washed by deionized water for several times. Then the sample was dried to constant weight at a temperature of 75°C in the oven for the next cycle. To analyze the active species generated in the process of photocatalytic degradation reaction and illustrate the possible mechanism, different trapping agents were put into the reaction mixtures. These scavenger making use of quenching reactive species include EDTA-2Na, TBA (tert-butyl alcohol), BQ (1,4-benzoquinone), and CCl4.

2.4. DFT calculation

The DFT calculation process was conducted through Vienna Ab initio Simulation Package (VASP) software4747 Kresse F. Efficient iterative schemes for ab initio total-energy calculations using a plane-wave basis set. Phys Rev B Condens Matter. 1996;54(16):11169-86. and spin-polarized Density Functional Theory (DFT). The exchange-correlation potential was calculated by Perdew-Burke-Ernzerhof functional (PBE)4848 Hohenberg P, Kohn W. Inhomogeiieous electron gas. Phys Rev. 1964;136(3B):864-71.,4949 Kohn W, Sham LJ. Self-consistent equations including exchange and correlation effects. Phys Rev. 1965;140:A1133. within the generalized gradient approximation (GGA) method5050 Perdew JP, Chevary JA, Vosko SH, Jackson KA, Pederson MR, Singh DJ, et al. Atoms, molecules, solids, and surfaces: applications of the generalized gradient approximation for exchange and correlation. Phys Rev B Condens Matter. 1992;46(11):6671-87.,5151 Perdew J, Burke K, Ernzerhof M. Generalized gradient approximation made simple. Phys Rev Lett. 1996;77:3865-8.. In the process of calculation, the cut-off energy was 450eV, and the K-points grids of dimensions were 5×5×5. Figure 3 displayed the theory structure of crystal NaSbO3 and ANS catalyst (Ag doped NaSbO3), the surface model of NaSbO3 and ANS catalyst. In addition, we calculated the band structure and DOS using crystal model of NaSbO3 (Figure 3a) and ANS catalyst (Figure 3b). We also computed the work function through the surface model of NaSbO3 (Figure 3c) and ANS catalyst (Figure 3d). The vacuum slab of surface model was designed as 30Å for both NaSbO3 and ANS catalyst. First of all, both the atomic coordinates and cell parameters of NaSbO3 and ANS catalyst were optimized in the process of calculation, respectively. The theoretical crystal structure of NaSbO3 is a cell unit, including 6Na, 6Sb and 18O atoms. The theoretical crystal structure of ANS catalyst is a cell unit, including 1Ag, 5Na, 6Sb, and 18O atoms.

Figure 3
The theory structure of crystal model NaSbO3 (a) and ANS Catalyst (b), and the theory structure of surface model (for work function calculation) NaSbO3 (c) and ANS catalyst (d) (yellow ball is Na atom, coffee ball is Sb atom, red ball is O atom, grey ball is Ag atom).

3. Results and Discussions

3.1. Particle size and liquid specific surface area

Figure 4a described the particle size of ANS Catalyst. It was observed that the particle size of ANS Catalyst ranged from 240nm to 6.607um (d0.1=705nm, d0.5=2.01um, d0.9=4.37 um). Figure 4b depicted the analytical results of the liquid-phase surface area for ANS Catalyst. According to the fitting calculation of instrument software, the liquid specific surface area of ANS Catalyst was about 543.7m2/g.

Figure 4
Particle size distribution and liquid specific surface area results of ANS Catalyst.

3.2. XRD

Figure 5 described XRD patterns of original NaSbO3 and ANS catalyst, respectively. For original NaSbO3, the main peaks could be found at 2θ, 14.9 º, 16.6 º, 20.1 º, 20.3 º, 28.8 º, 29.4 º, 29.6 º, 30.2 º, 33.8 º, 37.8 º, 48.4 º, and 50.4 º. In contrast, there were no obvious variations in the position of the peaks for the ANS Catalyst. This phenomenon indicated that NaSbO3 and AgSbO3 have similar crystal structure and atomic coordinates as theory structure in Figure.3a and 3b. In addition, some peaks of ANS Catalyst including 2θ at about 14.9 º, 16.6 º, 20.1 º, 20.3 º, 37.8 º and 48.4 º was obviously lower than that of NaSbO3. These results implied that the doping of Ag made the crystals of ANS Catalyst materials appear deformities and defects, resulting in the decrease of crystal integrity5252 Mohamed MA, Zain MFM, Minggu LJ, Kassim MB, Jaafar J, Amin NAS, et al. Bio-inspired hierarchical hetero-architectures of in-situ C-doped g-C3N4 grafted on C, N co-doped ZnO micro-flowers with booming solar photocatalytic activity. J Ind Eng Chem. 2019;77:393-407.

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Figure 5
XRD patterns of original NaSbO3 and ANS Catalyst.

3.3. UV–vis diffuse reflectance spectra

The results of UV-vis diffuse reflectance spectra were depicted in Figure 6. It could be observed that the broad absorption bands of NaSbO3 were approximately 300nm, while that of the ANS catalyst were 520nm. These findings indicated that ANS catalyst exhibited better visible light absorption than NaSbO3 after doping with Ag atom. For the calculation of band gap energy, Tauc equation is often used as follows:

Figure 6
UV-vis diffuse reflectance spectra of NaSbO3 and ANS Catalyst.
α ( v ) h v = A ( h v E g ) n / 2 (1)

55 55 Li P, Zhang W, Zhang X, Wang Z, Wang X, Ran S, et al. Synthesis, characterization, and photocatalytic properties of flower-like mn-doped ceria. Mater Res. 2018;21(5):1-6. , 56 56 Dai B, Xuan M, Lv Y, Jin C, Ran S. Molten salt synthesis of Bi2WO6 powders and its visible-light photocatalytic activity. Mater Res. 2019;22(5):1-7.

where, α, h, v, A and Eg represents absorption coefficient at light frequency v, Planck constant, light frequency, a constant and band gap energy, respectively. For direct transition semiconductor as NaSbO3, the value of n is 1.

According to Tauc equation, the value of Eg could be obtained through plotting the curve of [a(v)hv]22 Ben W, Zhu B, Yuan X, Zhang Y, Yang M, Qiang Z. Occurrence, removal and risk of organic micropollutants in wastewater treatment plants across China: comparison of wastewater treatment processes. Water Res. 2018;130:38-46. versus hv, and extra-polating the linear part of the curve to zero absorption coefficient. This analysis process for NaSbO3 and ANS catalyst was conducted, and the related findings were described in Figure 6b. We observed that the band gaps energy of NaSbO3 was 4.2eV, which was very similar to that of former reports4040 Singh J, Uma S. Efficient photocatalytic degradation of organic compounds by ilmenite AgSbO3 under visible and UV light irradiation. J Phys Chem C. 2009;113(28):12483-8.. Moreover, the band NaSbO3 gap energy of ANS catalyst was 2.3eV, which was much smaller than NaSbO3. These findings indicated that the doping of Ag atom could greatly reduce the band gap, and make ANS catalyst exhibit excellent absorption performance under visible light.

3.4. SEM-EDX

To further observe the microscopic morphology and composition of ANS catalyst, the SEM and EDX of sample was analyzed, and the results were depicted in Figure 7a to Figure 7c. It could be seen that ANS catalyst presented amorphous morphology. Besides, the EDX results (area 1) indicated that the main chemical composition (atomic percent/%) of ANS catalyst was about 2.47% Ag, 15.8% Na, 12.9% Sb, and 68.8% O. The coexistence of Ag with other elements confirmed that Ag atom had been doped into NaSbO3 molecules successfully.

Figure 7
The SEM and EDX results of ANS Catalyst (a. b and c), and the EDX element mapping of Sb (d), Ag (e), Na (f) and O (g).

Figure 7d to Figure 7g displayed the EDX element mapping of Sb, Ag, Na and O. It could be observed that the elements (Sb, Ag, Na and O) were mainly distributed in the position where the particles appeared in Figure 7b. In addition, there were significant similarities between the distribution of Ag and other elements through comparing Figure 7d-g. However, the distribution of Na was looser than that of O and Sb. This phenomenon could be explained as the replacement of Na atom by Ag atom in the crystal structure. In summary, the SEM and EDX analytical results were corresponded to the Ag doped NaSbO3 catalyst.

3.5. XPS

The surface chemical compositions of ANS catalyst were further confirmed by XPS, as shown as Figure 8. The mainly peaks of ANS catalyst were C1s (283eV), O1s (530eV), Ag3d (366eV and 372eV), Ag3p (570eV), Sb3d (538eV), Sb3p (768eV and 812eV), Na2s (54eV), and Na2p (33eV). Except for carbon (testing needs), all the other constituent elements could be found in ANS catalyst, which was corresponded to the results of other characterization techniques. In addition, the more details could be obtained from the high-resolution XPS spectra of O1s and Sb3d (Figure 8b). After a peak-fitting deconvolution, the strong peak ranging from 525eV to 534eV could be decomposed into two individual peaks (529eV and 530eV). The binding energies of O1s and Sb3d5/2 were very close. According to the theory area ration between Sb3d3/2 and Sb3d5/2, we speculated that peak located at 530.1eV was assigned to O1s, and peak located at 529.1eV was corresponded to Sb3d5/2. Besides, there also existed the binding energy shift (O1s, Sb3d3/2 and Sb3d5/2) in the survey spectrum, which might be explained as the bonds between O and other elements. According to the molecular structure of ANS catalyst, there are two kinds of Sb-O bonds with different bond lengths (1.97Å and 1.90Å), which may cause the binding energy shifts. Additionally, according to the theory peak position and area ration, the peaks of Ag3d5/2 and Ag3d3/2 in Figure 8c could be obtained at 366eV and 737eV. The peaks at 366eV and 737eV proved the existing of Ag+ in the ANS catalyst5757 Raja A, Rajasekaran P, Vishnu B, Selvakumar K, Yeon Do J, Swaminathan M, et al. Fabrication of effective visible-light-driven ternary Z-scheme ZnO-Ag-BiVO4 heterostructured photocatalyst for hexavalent chromium reduction. Separ Purif Tech. 2020;252:117446.,5858 Zhao W, Li Y, Zhao P, Zhang L, Dai B, Xu J, et al. Novel Z-scheme Ag-C3N4/SnS2 plasmonic heterojunction photocatalyst for degradation of tetracycline and H2 production. Chem Eng J. 2021;405:126555.. Consequently, the discovery of these peaks further confirmed that Ag atoms were successfully doped into NaSbO3 molecules. Figure 8d depicted the high-resolution XPS spectra of Na2p and Na2s. It was seen that the spectra of Na2p and Na2s could be observed at 33eV and 52eV, respectively. In conclusion, XPS spectra results further demonstrated the existence elements and their existing forms in ANS catalyst.

Figure 8
The wide scan XPS spectra (a) of ANS Catalyst; The high-resolution XPS spectra of (b) O1s and Sb 3d, (c) Ag3d, (d) Na2p and Na2s.

3.6. Photocatalytic activity

The photocatalytic activity of ANS catalyst was evaluated through the photocatalytic degradation of MB under visible light in solution, as shown as Figure 9. We investigated the effect of catalyst dosages on the photocatalytic degradation efficiencies of MB. Meanwhile, the degradation efficiencies of NaSbO3 and ANS without light on MB were also studied as comparisons, respectively. In the degradation process, it was seen from Figure 9a that the photodegradation efficiency of MB increased gradually with the increase of catalyst dosages under visible light. When the catalyst dosage was 0.67 g/L at10min, the degradation residual rate of MB achieved at 24%. As an efficient photocatalyst, such photodegradation efficiency could be acceptable. In addition, from the comparison of photocatalytic effect (Figure 9b), the addition of photocatalyst greatly promoted the degradation of MB, and the degradation rates for MB were better than that of other two systems. For instance, the residual rate of MB was approximately 11.1% just at 30min after adding ANS catalyst, while the residual rate were 74.3% at 30min with NaSbO3. However, the catalyst degradation efficiency of MB without illumination was significantly lower than that of the normal photocatalytic system, and the residual rate of MB was still 94.8% at 30min. These findings demonstrated that the doping of Ag atom greatly promoted the photocatalytic activity of NaSbO3 material. The varieties of UV-visible absorption spectra of MB at different reaction time were depicted in Figure 7f. It suggested that peaks of MB gradually decreased with the reaction time, which stated that MB displayed favorable photodegradation adding ANS catalyst. The photocatalytic performance of ANS catalyst is almost the similar as that of other latest photocatalytic materials (Nd3+ doped BaAl2O45959 Mumanga TJ, Díaz-Torres LA, Gómez-Solís C. Nd3+ doped BaAl2O4 for enhanced photocatalytic degradation of methylene blue. Mater Lett. 2021;292:129664., cobalt substituted zinc ferrite6060 Chahar D, Taneja S, Bisht S, Kesarwani S, Thakur P, Thakur A, et al. Photocatalytic activity of cobalt substituted zinc ferrite for the degradation of methylene blue dye under visible light irradiation. J Alloys Compd. 2021;851:156878., N self-doped TiO2/ZrO2 composite6161 Zheng J, Sun L, Jiao C, Shao Q, Lin J, Pan D, et al. Hydrothermally synthesized Ti/Zr bimetallic MOFs derived N self-doped TiO2/ZrO2 composite catalysts with enhanced photocatalytic degradation of methylene blue. Colloids Surf A Physicochem Eng Asp. 2021;623:126629., Ag@CdSe/Zeoilte nanocomposite6262 Mosavi SA, Ghadi A, Gharbani P, Mehrizad A. Photocatalytic removal of Methylene Blue using Ag@CdSe/Zeoilte nanocomposite under visible light irradiation by Response Surface Methodology. Mater Chem Phys. 2021;267:124696., CQDs/CeO2/SrFe12O196363 Wang S, Gao H, Fang L, Hu Q, Sun G, Chen X, et al. Synthesis of novel CQDs/CeO2/SrFe12O19 magnetic separation photocatalysts and synergic adsorption-photocatalytic degradation effect for methylene blue dye removal. Adv Chem Eng. 2021;6:100089.). Besides, we investigated the apparent degradation kinetics via first-order reaction model, and the equation of which is as follows. The reaction constant k (min-1) and half life of the reactions (min) can be obtained by fitting the experimental results via the Equations 2 and 3.

Figure 9
(a) The effect of ANS Catalyst dosage on the removal rate of MB; (b) The photodegradation effect of ANS Catalyst under visible light, NaSbO3, and ANS Catalyst with no light; (c) the apparent fitting findings using the pseudo-first-order model; (d) the constants of first-order reactions for MB photodegradation; (e) The half life of photocatalysis reactions; (f) UV-visible absorption spectra of MB solution degraded by ANS Catalyst.
L n C C 0 = k t (2)

8 8 Zhang X, Cheng T, Chen C, Wang L, Deng Q, Chen G, et al. Synthesis of a novel magnetic nano-zeolite and its application as an efficient heavy metal adsorbent. Mater Res Express. 2020;7(8):085007. , 64 64 Cheng T, Chen C, Wang L, Zhang X, Ye C, Deng Q, et al. Synthesis of fly ash magnetic glass microsphere@BiVO4 and its hybrid action of visible-light photocatalysis and adsorption process. Pol J Environ Stud. 2021;30(3):2027-40.

T h a l f l i f e = L n ( 2 ) k (3)

65 65 Collins SM, Pearce AK, Ferreira KM, Fenwick AJ, Regan PH, Keightley JD. Direct measurement of the half-life of (223)Ra. Appl Radiat Isot. 2015;99:46-53.

Where, C0 represents the initial concentration of MB, and Ct represents the concentration of MB at time t

Figure 9c presented the fitting results of apparent kinetics utilizing the Equation 2 (based on the data in Figure 9b). The R2 values fitted by the equation were 0.9983, 0.99519, and 0.9651, respectively. They were all above 0.96, which indicated that the apparent photocatalytic degradation process of MB could be satisfactorily fitted by first-order reaction model. Additionally, the k value of ANS photogradation system from Figure 7d was 0.0823, which was the largest in three systems. At the same time, the addition of ANS Catalyst greatly reduced the half-life of the reaction (Figure 9e). The half-life of ANS reaction system was about 8.42 min, and that of the other two systems were about 383 min (no-light system) and 86 min (NaSbO3 system), respectively.

Furthermore, we measured the photocatalytic performance of recycled ANS through identifying the photodegradation efficiencies of MB under visible light. The morphology and XRD patterns of reused ANS after three times were also analyzed, as shown as Figure 10. It was seen that, the catalyst maintained amorphous state in comparison of the original sample after the consecutive three times of photocatalysis experiment (Figure 10a). Moreover, it was no obvious variations in the overall appearance of ANS particles. From XRD patterns of ANS after 3rd photocatalysis experiment (Figure 10b), we found that the main peaks could also be appeared contrast with the previous results. Additionally, according to the reuse photodegradation curves of ANS (Figure 10c), there was only a slight reduction of photocatalytic activities after three cycles of recycle, which verified that ANS possessed remarkable photocatalytic stability, and the ANS catalyst could be efficiently reused.

Figure 10
(a) The morphology of catalyst after 3rd photocatalysis experiment ; (b) The XRD patterns of ANS Catalyst before and after 3rd photocatalysis experiment; (c) the degradation curve of ANS catalyst reuse under visible light

3.7. Photodegradation mechanism

The transient photocurrent response of ANS catalyst and NaSbO3 under Xe lamp irradiation was described in Figure 11a. It was seen that NaSbO3 only appeared slight response due to its bigger band gaps energy (4.5eV), which made NaSbO3 unable to enough excite electrons and holes out under visible light. On the contrary, the photocurrent intensity of ANS catalyst enhanced greatly after the doping of Ag atoms, confirming that ANS catalyst possessed stronger ability of generating and transferring electrons and holes under visible light.

Figure 11
(a) Transient photocurrent responses of ANS Catalyst and NaSbO3 under visible-light irradiation; (b) Electrochemical impedance spectra of ANS Catalyst and NaSbO3; (c) Steady-state PL spectra of ANS Catalyst and NaSbO3; (d) Mott-Schottky curves of ANS Catalyst; (e) photodegradation efficiency by addition of trapping agents; (f) ESR spectra of radical adducts trapped by DMPO in the dark and under visible light irradiation for DMPO-·OH; (g) ESR spectra of radical adducts trapped by DMPO in the dark and under visible light irradiation for DMPO-·O2-.

Figure 11b depicted the EIS value of ANS catalyst and NaSbO3. The radius values of NaSbO3 were bigger than that of ANS, stating that the doped Ag atoms reduced the resistance of charge transfer, thus effectively promoted the reaction process of photocatalysis. In addition, the PL emission spectrum was further conducted to evaluate the combination and separation of photogenerated electrons and holes, as shown in Figure 11c. It was observed that the PL emission spectrum of ANS displayed significant red shift compared with NaSbO3. This stated that the photoluminescence energy of catalyst was lower than that of NaSbO3, and that might be ascribed to the smaller band energy of ANS catalyst. Also, the photoluminescence spectrum intensity of ANS Catalyst did not become stronger than that of NaSbO3, which suggested the Ag atoms doped could not enhance the combination probability of photogenerated electrons and holes4242 Mao S, Shi J, Sun G, Ma D, He C, Pu Z, et al. Au nanodots@thiol-UiO66@ZnIn2S4 nanosheets with significantly enhanced visible-light photocatalytic H2 evolution: the effect of different Au positions on the transfer of electron-hole pairs. Appl Catal B. 2021;282:119550.,4343 Wang K, Xing Z, Meng D, Zhang S, Li Z, Pan K, et al. Hollow MoSe2@Bi2S3/CdS Core-Shell nanostructure as dual Z-Scheme heterojunctions with enhanced full spectrum photocatalytic-photothermal performance. Appl Catal B. 2021;281:119482.. Figure 11d showed the Mott–Schottky measurements of ANS Catalyst. The displayed negative slopes indicated that ANS Catalyst was p-type semiconductors5858 Zhao W, Li Y, Zhao P, Zhang L, Dai B, Xu J, et al. Novel Z-scheme Ag-C3N4/SnS2 plasmonic heterojunction photocatalyst for degradation of tetracycline and H2 production. Chem Eng J. 2021;405:126555.. In addition, the flat-band potential (Vfb) could be obtained by M-S curves, corresponding to the intercepts of the X axis6161 Zheng J, Sun L, Jiao C, Shao Q, Lin J, Pan D, et al. Hydrothermally synthesized Ti/Zr bimetallic MOFs derived N self-doped TiO2/ZrO2 composite catalysts with enhanced photocatalytic degradation of methylene blue. Colloids Surf A Physicochem Eng Asp. 2021;623:126629.. The Vfb of ANS Catalyst was 2.44V (vs NHE). Because the valence band (VB) potential (EVB) of p-type semiconductors is 0.2V positive than Vfb in theory6161 Zheng J, Sun L, Jiao C, Shao Q, Lin J, Pan D, et al. Hydrothermally synthesized Ti/Zr bimetallic MOFs derived N self-doped TiO2/ZrO2 composite catalysts with enhanced photocatalytic degradation of methylene blue. Colloids Surf A Physicochem Eng Asp. 2021;623:126629., the EVB of ANS Catalyst should be around 2.64V. Combined with previous UV–vis analysis, the range between ECB (conduction band potential) and EVB should be 0.34V-2.64V. After unit conversion, the range should be -4.84eV to -7.14ev.

It is known that, the photocatalytic degradation process of organic pollutants mainly depends on the strong redox of free electrons, holes and related free radicals released by photocatalysts. To evaluate which species playing active roles in the process of photocalytic degradation reaction, we took advantage of trapping agents putting into the reaction mixtures. On the basis of references6666 Tang H, Fu Y, Chang S, Xie S, Tang G. Construction of Ag3PO4/Ag2MoO4 Z-scheme heterogeneous photocatalyst for the remediation of organic pollutants. Chin J Catal. 2017;38(2):337-47.,6767 Zhu D, Zhou Q. Nitrogen doped g-C3N4 with the extremely narrow band gap for excellent photocatalytic activities under visible light. Appl Catal B. 2021;281:119474., EDTA-2Na could be used as a hole trapper, TBA as a hydroxyl radical trapper, BQ as an oxygen free radical trapper, and CCl4 as an electron trapper. Figure 11e described the effect of different trapping agents on the photocatalytic activity of MB. It displayed that the photocatalytic efficiencies of ANS catalyst were all decreased after adding trapping agents. This phenomenon confirmed that the photocatalytic activities were inhibited with the coexistent of these scavengers, and photocatalytic degradation path from Equation 4, 5, 6 was probably happen during the degradation process.

O 2 + e O 2 (4)
O 2 + MB D e g r a d a t i o n - p r o d u c t s (5)
H 2 O / OH + h + OH (6)
OH + MB D e g r a d a t i o n - p r o d u c t s (7)

Furthermore, ESR spin-trapping spectra were measured using the DMPO technique to detect the hydroxyl radicals (DMPO-•OH) and the superoxide radicals (DMPO-·O2-), to prove the action mechanism of active radicals in photocatalytic reaction, as shown as Figure 11f and Figure 11g. In both NaSbO3 and ANS catalyst absence of light system, there was no characteristic peaks of·OH or·O2- were measured. That indicated in both NaSbO3 and ANS lack of light system, there were no excited electrons and holes. Accordingly,·OH or·O2- would not be appeared. In contrast, the typical peaks of •OH with the intensity ratio of 1:2:2:1 and that of •O2- were detected under visible light irradiation6868 Kim D, Yong K. Boron doping induced charge transfer switching of a C3N4/ZnO photocatalyst from Z-scheme to type II to enhance photocatalytic hydrogen production. Appl Catal B. 2021;282:119538.,6969 Wong KT, Kim SC, Yun K, Choong CE, Nah IW, Jeon B-H, et al. Understanding the potential band position and e-/h(+) separation lifetime for Z-scheme and type-II heterojunction mechanisms for effective micropollutant mineralization: comparative experimental and DFT studies. Appl Catal B. 2020;273:119034., which demonstrated that both•OH and •O2- were produced in the process of ANS photocatalytic degradation. Moreover, these findings were in line with that of Figure 11f. The action process of these free radicals might be one of the main photocatalytic mechanisms for pollutant degradation. Besides, among these scavengers, EDTA-2Na and TBA exhibited more obvious influences on the photocatalytic reaction process. Additionally, these findings implied that the capture of holes and hydroxyl radicals was likely to seriously lower the photodegradation activity, which might be explained by the main degradation path of MB as Equation 5 and 6 under ANS photocatalytic system.

To further clarify the photocatalytic mechanism of ANS catalyst, the VASP software was utilized to investigate the DFT calculation for NaSbO3 and ANS catalyst. The structure of the material was optimized theoretically, and the optimized structures of NaSbO3 and ANS catalyst were shown in Figure 3a. In the process of constructing the crystal structure of ANS catalyst, a Na atom in the original NaSbO3 crystal was replaced by an Ag atom, as shown as Figure 2b, and the lattice parameters before and after doping was shown in Table 1. It was observed that the crystal parameters of NaSbO3 and ANS Catalyst calculated theoretically were different from the experimental results. However, the theoretical calculations also indicated that the unit cell parameters of ANS Catalyst were smaller than that of NaSbO3 through the doping of Ag, which was consistent with the results obtained by the previous XRD analysis. By comparing Figure 3a and Figure 3b, it could be seen that a Na atom in the crystal structure of NasbO3 was replaced by an Ag atom, and its atomic coordinates changed from (0.667, 0.333, 0.975) to (0.667, 0.333, 0.929). According to the calculation results of atomic proportion in the theory model (Figure 3b), the proportion of doped Ag is about 3.3%. The proportion of Ag element in EDX and XPS analysis results is 2.47% and 3.86%, respectively. Considering the difference between experiment data and theoretical analysis, the theoretical model of ANS could be acceptable. The lattice parameters of the crystal structure had also changed (Table 1).

Table 1
The lattice parameters before and after doping (DFT calculation).

On the basis of structure optimization, we calculated the charge density of NaSbO3 and ANS catalyst, as shown as Figure 12 (Charge density distribution). The charge was mainly distributed around the atomic position, which indicated that bonds of Ag-O and Na-O in the crystal structure were both typical ionic bonds. The length of Ag-O bond was 2.053 Å, and the bond angle was 96.59 deg (Figure 12c). While the length of Na-O bond was 2.038Å, and the bond angle was 103.2 deg (Figure 12d). In addition, we observed the charge of Ag atoms in Figure 12a. This phenomenon indicated that Ag atom doping into NaSbO3 was extremely stable presented in the crystal. Moreover, the charge of Na atom could not be observed in Figure 12b, which might due to the fact that Na atom was far away from the charge density center.

Figure 12
Charge density distribution (0 0 1 surface, distance from origin is 0.1d) of ANS Catalyst (a) and NaSbO3 (b).

Figure 13 displayed the DOS calculation results of NaSbO3 and ANS catalyst. According to the computation findings (Figure 13a and Figure 13b), the band gaps of NaSbO3 and ANS catalyst were 4.15eV and 2.05eV, respectively, which was close to that of the analytical results of diffuse reflection. By comparing Figure 13a with Figure 13b, it was seen that the reduction in the band gap of ANS catalyst was due to the appearance of some new state densities near Fermi energy level of original NaSbO3, which was mainly contributed by the d orbital of Ag atoms doped in the crystals. Similar results could also be obtained from the energy band calculation results in Figure 14. We observed that NaSbO3 was a typical direct band gap semiconductor (Figure 14a), and many additional bands appeared near Fermi energy level of original NaSbO3 by doping Ag atoms. The addition of these energy bands greatly reduced the band gap of ANS catalyst to 2.05eV. Hence, theoretically, the doping of Ag atoms provided a suitable additional band, which made ANS catalyst exhibit remarkable visible light absorption performances.

Figure 13
Density of States of NaSbO3 (a), ANS Catalyst (b) and pDOS of Ag atom in ANS Catalyst (c).
Figure 14
The band structure of NaSbO3 (a), ANS Catalyst (b).

Figure 15 depicted the theoretical calculation results of optical properties for NaSbO3 and ANS catalyst. The overall optical properties of NaSbO3 and ANS catalyst were relatively similar (Figure 15a, c). However, through comparing Figure 15b and Figure 15d, it was seen that the visible light absorption of ANS catalyst was significantly higher than that of NaSbO3 under visible light ranged from 1eV to 3eV. Especially in xy direction of crystal, the maximum visible light absorption coefficient of NaSbO3 crystal was 0.06(105cm-1), while the visible light coefficient curve of ANS catalystl was significantly higher, and the maximum value was 0.16 (105cm-1). These findings confirmed that the doping of Ag ion effectively improved the visible light absorption of material, which was very beneficial to the improvement of photocatalytic performance.

Figure 15
The calculation optical properties of NaSbO3 (a), NaSbO3 under visible light (b), ANS Catalyst (c), ANS Catalyst under visible light (d).

Figure 16 displayed the calculation results of work function for NaSbO3 and ANS catalyst. The work function of NaSbO3 and ANS catalyst were 4.63eV and 6.72eV, respectively. The calculation results of the range between ECB and EVB was basically consistent with the previous Mott-Schottky curves results. This phenomenon indicated that the doping of Ag atoms not only reduced the band gap of material, but also improved the work function. By reducing the band gap, the catalyst displayed obvious visible light excitation performance. Moreover, the improvement of work function enhanced the oxidation ability of photogenerated holes, and more hydroxyl radicals were formed in system, making the oxidation of photogenerated holes and the reaction of hydroxyl radicals became the main mechanism for degrading pollutants. These findings were in line with previous photocatalytic results in hydroxyl radical and photogenerated hole trapping agent systems. The schematic diagram for the whole photocatalytic degradation mechanism by Ag doped NaSbO3 in this reaction was described in Figure 17.

Figure 16
Work function of NaSbO3 (a) and ANS Catalyst (b), Comparison of energy band structures of NaSbO3 and ANS Catalyst.
Figure 17
Schematic diagram of photocatalytic degradation by Ag doped NaSbO3 (ANS catalyst).

4. Conclusions

A photocatalyst, ANS catalyst, was prepared, characterized, and applied to the photocatalytic degradation of MB. The properties of ANS catalyst were fully measured by various instruments. The characterization results confirmed that, the doping of Ag atoms into NaSbO3 crystals reduced the band gap, and ANS catalyst exhibited favorable absorption performance of visible light. The photodegradation experiments stated that ANS catalyst effectively enhanced the photocatalytic degradation of MB under visible light, and the first-order reaction model could perfectly fit the process of photodegradation. In addition, ANS catalyst displayed excellent photocatalytic performance after consecutive three times of recycle. The electrochemical experiments findings revealed that ANS catalyst had a strong ability to generate and transfer electrons and holes under visible light. Ag atoms doping into NaSbO3 decreased the resistance of charge transfer. Accordingly, the photocatalytic degradation of MB was greatly enhanced. Besides, The active species of •OH and •O2- could be detected in the photodegradation process, and they were vital to the photocatalytic reaction. DFT computation illustrated that, by doping with Ag atoms, many additional energy bands appeared near Fermi energy level of NaSbO3, which greatly reduced the band gap of ANS catalyst to 2.05eV, and thus favored to effective absorb visible light. Additionally, the workfunction was improved during the photocatalytic process, which could increase the oxidation ability of photogenerated holes, and form more hydroxyl radicals, and then accelerate the photocatalytic degradation of MB.

Acknowledgements

This work is supported by Science Foundation of Jiangsu Colleges and Universities (Grant No. 17KJD610001, 17KJD610002).

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Publication Dates

  • Publication in this collection
    27 Aug 2021
  • Date of issue
    2021

History

  • Received
    24 Feb 2021
  • Reviewed
    18 July 2021
  • Accepted
    01 Aug 2021
ABM, ABC, ABPol UFSCar - Dep. de Engenharia de Materiais, Rod. Washington Luiz, km 235, 13565-905 - São Carlos - SP- Brasil. Tel (55 16) 3351-9487 - São Carlos - SP - Brazil
E-mail: pessan@ufscar.br