PHOTOCATALYTIC MATERIAL FOR EFFICIENT PHOTOCATALYTIC REMOVAL OF HIGH-CONCENTRATION NITRATE, AND PREPARATION METHOD AND USE THEREOF

Abstract

A photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate, and a preparation method and use thereof are disclosed. The preparation method includes the following steps: step 1: preparation of a citrate-stabilized silver nanoparticle; step 2: synthesis and functionalization modification of SiO.sub.2 step 3: preparation of Ag/SiO.sub.2; and step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure. The photocatalytic material prepared by the present disclosure has high reduction catalytic activity and can quickly remove a high-concentration nitrate and achieve high nitrogen selectivity. In addition, due to protection of a titanium dioxide shell, the photocatalytic material has excellent stability and can remove a high-concentration nitrate in water when the nitrate coexists with a high-concentration chloride ion.

Claims

1. A preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate, comprising the following steps: step 1: preparation of a citrate-stabilized silver nanoparticle: adding a sodium citrate solution to a silver nitrate solution, adding a sodium borohydride solution dropwise to a resulting mixed solution at room temperature, and stirring to obtain a silver nanoparticle colloid solution; step 2: synthesis and functionalization modification of SiO.sub.2: adding a first tetraethyl orthosilicate (TEOS) dropwise to a first mixed solution of water, ammonia water, and isopropyl alcohol (IPA), stirring a first resulting mixture in a water bath to continue a reaction to obtain a silicon dioxide (SiO.sub.2) seed, adding a second TEOS dropwise to a resulting reaction system to allow a first reaction, and conducting a first post-treatment to obtain a SiO.sub.2 microsphere; and ultrasonically dispersing the SiO.sub.2 microsphere in ethanol, adding (3-aminopropyl) triethoxysilane (APTES), stirring a second resulting mixture in a water bath, and conducting a second post-treatment to obtain APTES-SiO.sub.2; step 3: preparation of Ag/SiO.sub.2: dispersing APTES-SiO.sub.2 in deionized water, adding the silver nanoparticle colloid solution dropwise, stirring, and conducting a third post-treatment to obtain Ag/SiO.sub.2; and step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: ultrasonically dispersing Ag/SiO.sub.2 uniformly in ethanol, and adding hexadecylamine (HDA) and ammonia water; stirring a third resulting mixture at room temperature for uniform dispersion, during stirring, titanium isopropoxide is added to allow a second reaction; collecting Ag/SiO2@aTiO2 with an amorphous titanium dioxide shell through centrifugation; dispersing Ag/SiO.sub.2@aTiO.sub.2 in a second mixed solution of ethanol and water, transferring a resulting solution to a reactor, and placing the reactor at a high temperature to allow a third reaction; and after the reaction is completed, cooling the reactor to room temperature, and subjecting a resulting product to a fourth post-treatment and then to calcination to obtain Ag/SiO2@cTiO2 with a crystalline titanium dioxide shell.

2. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 1, the sodium borohydride solution, the sodium citrate solution, and the silver nitrate solution are in a volume ratio of 1:4:50 and in a concentration ratio of 112:40:1.

3. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 2, the first TEOS and the first mixed solution for preparing the SiO.sub.2 seed and the second TEOS added later are in a volume ratio of 0.6:100:5; the water, the ammonia water, and the IPA in the first mixed solution are in a volume ratio of 5:3:12; and the first water bath for preparing the SiO.sub.2 seed has a temperature of 30° C. to 40° C.

4. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 2, a concentration of the SiO.sub.2 microsphere dispersed in the ethanol is 2 g/L; a volume ratio of the APTES to the ethanol is 1:100; and the second water bath for modification with the APTES has a temperature of 50° C. to 60° C.

5. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 3, a concentration of the APTES-SiO.sub.2 dispersed in the deionized water is 0.5 g/L; the silver nanoparticle colloid solution has a concentration of 0.1 mg/L; and a volume ratio of the silver nanoparticle colloid solution to the deionized water is (1-10):40.

6. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 4, during the preparation of the Ag/SiO.sub.2@aTiO.sub.2, a concentration of each of the Ag/SiO.sub.2 and the HDA dispersed in the ethanol is 8 g/L; the ammonia water, the titanium isopropoxide, and the ethanol are in a volume ratio of 1:1:50; and the second reaction is conducted for 10 minutes.

7. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 4, during the preparation of the Ag/SiO.sub.2@cTiO.sub.2, a concentration of the Ag/SiO.sub.2@aTiO.sub.2 dispersed in the second mixed solution of the ethanol and water is 0.67 g/L, and a ratio of the ethanol to the water in the second mixed solution is 2:1.

8. The preparation method of the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 1, wherein in step 4, the reactor is a stainless-steel high-pressure reactor lined with polytetrafluoroethylene (PTFE); the third reaction in the reactor is conducted at 140° C. to 160° C. for 12 h to 16 h; and the calcination is conducted at 400° C. to 500° C. for 2 h with a heating rate of 5° C./min.

9. A photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate prepared by the preparation method according to claim 1.

10. A method of using the photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, comprising: providing the photocatalytic material in water, and removal of a nitrate ion in the water through photocatalytic reduction.

11. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 1, the sodium borohydride solution, the sodium citrate solution, and the silver nitrate solution are in a volume ratio of 1:4:50 and in a concentration ratio of 112:40:1.

12. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 2, the first TEOS and the first mixed solution for preparing the SiO.sub.2 seed and the second TEOS added later are in a volume ratio of 0.6:100:5; the water, the ammonia water, and the IPA in the first mixed solution are in a volume ratio of 5:3:12; and the water bath for preparing the SiO.sub.2 seed has a temperature of 30° C. to 40° C.

13. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 2, a concentration of the SiO.sub.2 microsphere dispersed in the ethanol is 2 g/L; a volume ratio of the APTES to the ethanol is 1:100; and the water bath for modification with the APTES has a temperature of 50° C. to 60° C.

14. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 3, a concentration of the APTES-SiO.sub.2 dispersed in the deionized water is 0.5 g/L; the silver nanoparticle colloid solution has a concentration of 0.1 mg/L; and a volume ratio of the silver nanoparticle colloid solution to the deionized water is (1-10):40.

15. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 4, during the preparation of the Ag/SiO.sub.2@aTiO.sub.2, a concentration of each of the Ag/SiO.sub.2 and the HDA dispersed in the ethanol is 8 g/L; the ammonia water, the titanium isopropoxide, and the ethanol are in a volume ratio of 1:1:50; and the second reaction is conducted for 10 minutes.

16. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 4, during the preparation of the Ag/SiO.sub.2@cTiO.sub.2, a concentration of the Ag/SiO.sub.2@aTiO.sub.2 dispersed in the second mixed solution of the ethanol and water is 0.67 g/L, and a ratio of the ethanol to the water in the second mixed solution is 2:1.

17. The photocatalytic material for efficient photocatalytic removal of the high-concentration nitrate according to claim 9, wherein in step 4, the reactor is a stainless-steel high-pressure reactor lined with polytetrafluoroethylene (PTFE); the third reaction in the reactor is conducted at 140° C. to 160° C. for 12 h to 16 h; and the calcination is conducted at 400° C. to 500° C. for 2 h with a heating rate of 5° C./min.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0028] FIG. 1a is a transmission electron microscopy (TEM) image of the Ag nanoparticle obtained in step 1;

[0029] FIG. 1B is a scanning electron microscopy (SEM) image of the SiO.sub.2 obtained in step 2;

[0030] FIG. 1c is an SEM image of the Ag/SiO.sub.2 obtained in step 3;

[0031] FIG. 1d is an SEM image of the final product Ag/SiO.sub.2@cTiO.sub.2;

[0032] FIG. 1e is a TEM image of the final product Ag/SiO.sub.2@cTiO.sub.2;

[0033] FIG. 2 shows X-ray diffraction (XRD) patterns of SiO.sub.2, 5% Ag/SiO.sub.2@aTiO.sub.2, and 5% Ag/SiO.sub.2@cTiO.sub.2;

[0034] FIG. 3 shows X-ray photoelectron spectroscopy (XPS) spectra of SiO.sub.2, 5% Ag/SiO.sub.2@aTiO.sub.2, and 5% Ag/SiO.sub.2@cTiO.sub.2;

[0035] FIG. 4 shows ultraviolet-visible (UV-vis) absorption spectra of SiO.sub.2 and Ag/SiO.sub.2@cTiO.sub.2 samples with different Ag nanoparticle contents;

[0036] FIG. 5a and FIG. 5b show spatial electric field distributions of SiO.sub.2@cTiO.sub.2 (SiO.sub.2-coated crystal TiO.sub.2 without an Ag load) and Ag/SiO.sub.2@cTiO.sub.2 calculated by a 3D time-domain finite-difference method, respectively;

[0037] FIG. 6 shows photocatalytic reduction effects of various catalysts for a low-concentration nitrate ion (100 mg/L) in Example 2;

[0038] FIG. 7 shows the changes in nitrogen-containing product concentrations and nitrogen selectivity during photocatalytic reduction of various catalysts for a high-concentration nitrate ion (2,000 mg/L) in Example 3;

[0039] FIG. 8 shows a recycling effect of 5% Ag/SiO.sub.2@cTiO.sub.2 in reduction of a high-concentration nitrate ion (2,000 mg/L) in Example 4;

[0040] FIG. 9 shows a reduction effect of 5% Ag/SiO.sub.2@cTiO.sub.2 for a high-concentration nitrate ion (2,000 mg/L) coexisting with a high-concentration chloride ion (NaCl=4 wt % to 10 wt %) in Example 5; and

[0041] FIG. 10 shows XPS spectra before and after a reaction of 5% Ag/SiO.sub.2@cTiO.sub.2 in Example 5.

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0042] The present disclosure will be further described below in conjunction with specific examples.

Example 1

[0043] In this example, a preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate was provided, including the following steps:

[0044] Step 1: preparation of a citrate-stabilized silver nanoparticle: 8 mL of a 40 mmol.Math.L.sup.−1 sodium citrate solution was added as a stabilizer to 100 mL of a 1 mmol.Math.L.sup.−1 silver nitrate solution; 2 mL of a 112 mmol.Math.L.sup.−1 NaBH.sub.4 solution was added dropwise to a resulting mixed solution at room temperature, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) to obtain a yellow-brown silver nanoparticle sol solution; and the yellow-brown silver nanoparticle sol solution was stored in a 4° C. refrigerator and allowed to stand for 24 h to allow decomposition of residual NaBH.sub.4 for later use.

[0045] Step 2: synthesis and functionalization modification of SiO.sub.2: 0.6 mL of TEOS was added dropwise to a mixed solution of 25 mL of water, 15 mL of ammonia water, and 60 mL of IPA, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) in a 35° C. water bath to allow a reaction for 30 minutes to obtain a silicon dioxide seed; then 5 mL of TEOS was added dropwise to a resulting reaction system to allow a reaction for 2 h, and a resulting product was collected through centrifugation, washed, and dried to obtain a SiO.sub.2 microsphere. In order to make a surface of SiO.sub.2 positively charged, 0.4 g of the synthesized SiO.sub.2 was ultrasonically dispersed in 200 mL of ethanol, then 2 mL of APTES was added, and a resulting mixture was stirred in a 60° C. water bath for 4 h; and a product was collected through centrifugation, repeatedly washed with ethanol, and dried to obtain APTES-SiO.sub.2.

[0046] Step 3: preparation of Ag/SiO.sub.2: 0.2 g of APTES-SiO.sub.2 was dispersed in 400 mL of deionized water, then 20 mL of a 0.1 mg.Math.L.sup.−1 silver nanoparticle colloid solution (which was obtained by diluting the silver nanoparticle colloid solution obtained in step 1) was added dropwise, and a resulting mixture was vigorously stirred for 1 h (1,000 rpm to 1,400 rpm); and finally a product was collected through suction filtration, washed, and dried to obtain 1 wt % Ag/SiO.sub.2.

[0047] An amount of the silver nanoparticle colloid solution could be changed to obtain SiO.sub.2 samples loaded with Ag in different proportions. A volume ratio of the silver nanoparticle colloid solution to the deionized water was (1-10):40. In this example, 0.5 wt %, 2 wt %, and 5 wt % Ag/SiO.sub.2 samples were prepared by changing the amount of the silver nanoparticle colloid solution.

[0048] Step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: 0.08 g of Ag/SiO.sub.2 was ultrasonically dispersed in 10 mL of ethanol uniformly, 0.08 g of HDA and 0.2 mL of ammonia water were added, and a resulting mixture was stirred at room temperature for uniform dispersion, during which 0.2 mL of titanium isopropoxide was added to allow a reaction for 10 minutes; the Ag/SiO.sub.2@aTiO.sub.2 with an amorphous titanium dioxide shell was collected through centrifugation, and then washed three times with each of water and ethanol; [0049] in order to prepare Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline TiO.sub.2 shell, the Ag/SiO.sub.2@aTiO.sub.2 sphere was subjected to a hydrothermal treatment as follows: Ag/SiO.sub.2@aTiO.sub.2 (0.02 g) was dispersed in a mixed solution of 20 mL of ethanol and 10 mL of water, a resulting solution was then transferred to a stainless-steel high-pressure reactor lined with PTFE, and the reactor was placed in a high-temperature oven to allow a reaction at 160° C. for 16 h; and the reactor was cooled to room temperature, and a product was collected through centrifugation, washed, dried, and finally subjected to calcination at 450° C. for 2 h in a muffle furnace to obtain Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline titanium dioxide shell.

[0050] The product obtained in each step was characterized by SEM and TEM. It can be seen from FIG. 1 that the Ag nanoparticles and SiO.sub.2 are dispersed and have average particle sizes of 6.7 nm and 420 nm, respectively; the Ag nanoparticles can be uniformly distributed on a surface of SiO.sub.2; and after the hydrothermal and calcination treatments, an anatase titanium oxide shell with a rough and porous surface is obtained.

[0051] It can be seen from FIG. 2 that SiO.sub.2 and 5% Ag/SiO.sub.2@aTiO.sub.2 (amorphous) samples have similar XRD patterns, in which there is a wide peak at about 23° corresponding to amorphous silicon dioxide; and in the XRD pattern of 5% Ag/SiO.sub.2@aTiO.sub.2 (amorphous), the intensity of the diffraction peak of silicon dioxide is weakened and the characteristic peak of TiO.sub.2 does not appear, which is due to the coverage of the amorphous TiO.sub.2 shell. The 5% Ag/SiO.sub.2@cTiO.sub.2 (crystal) obtained after hydrothermal and calcination treatments has a TiO.sub.2 shell with excellent crystallinity, and in its XRD pattern, an obvious characteristic peak of the anatase crystal appears.

[0052] It can be seen from the XPS full spectra (FIG. 3) of 5% Ag/SiO.sub.2, 5% Ag/SiO.sub.2@aTiO.sub.2, and 5% Ag/SiO.sub.2@cTiO.sub.2 (crystal) that the electron binding energy values of 103.5 eV, 153.4 eV, 284.4 eV, 368 eV, 460.1 eV, 531.1 eV, and 974.8 eV correspond to the characteristic peaks of Si 2P, Si 2s, C 1s, Ag 3d, Ti 2p, and O 1s energy levels and the Auger peak of O, respectively. After a TiO.sub.2 layer is coated on a surface of 5% Ag/SiO.sub.2, the characteristic peak of the Ti 2p energy level appears in the XPS spectra of 5% Ag/SiO.sub.2@aTiO.sub.2 and 5% Ag/SiO.sub.2@cTiO.sub.2. Since 5% Ag/SiO.sub.2@aTiO.sub.2 has an additional amorphous TiO.sub.2 shell compared with 5% Ag/SiO.sub.2, the characteristic peaks corresponding to the 2p and 2s energy levels of Si and the 3d energy level of Ag are weak and can hardly be observed in the XPS full spectrum; and the characteristic peaks of Si appear in the XPS spectrum of 5% Ag/SiO.sub.2@cTiO.sub.2 obtained after the hydrothermal and calcination treatments, which is due to the fact that the HDA surfactant in the TiO.sub.2 shell is completely cleared after the hydrothermal and calcination treatments to form a rough and porous structure in the smooth TiO.sub.2 shell, thereby weakening the coverage of SiO.sub.2.

[0053] FIG. 4 shows UV-vis diffuse reflection spectra. When no Ag nanoparticle is loaded, no absorption peak for SiO.sub.2@TiO.sub.2 appears at 400 nm to 500 nm. However, when silver is loaded at different contents, an obvious absorption peak for Ag/SiO.sub.2@cTiO.sub.2 appears at 437 nm, and an intensity of the absorption peak is almost increased linearly with the increase in Ag content.

[0054] FIG. 5a and FIG. 5b show spatial electric field distributions of SiO.sub.2@cTiO.sub.2 (SiO.sub.2-coated crystal TiO.sub.2 without an Ag load) and Ag/SiO.sub.2@cTiO.sub.2 calculated by a 3D time-domain finite-difference method, respectively. In FIG. 5a, 365 nm linear polarized light is injected along the Z axis, and it can be seen that an electric field intensity at an interface between silicon dioxide and titanium dioxide increases significantly, indicating that the light scattering effect enhances the capture of light, the excitation at the core-shell interface is enhanced, and the frontier electron density is increased. In FIG. 5b, 425 nm linear polarized light is injected along the Z axis, and it can be seen that Ag nanoparticles at the core-shell interface are excited by SPR to produce an obvious thermal field, indicating that the light scattering effect of the core-shell model improves the light capture efficiency of Ag/and SiO.sub.2@cTiO.sub.2, promotes the SPR excitation for Ag nanoparticles, and enhances the electron density on the surface of the catalyst.

Example 2

[0055] In this example, a preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate was provided, including the following steps: [0056] Step 1: preparation of a citrate-stabilized silver nanoparticle: 8 mL of a 40 mmol.Math.L.sup.−1 sodium citrate solution was added as a stabilizer to 100 mL of a 1 mmol.Math.L.sup.−1 silver nitrate solution; 2 mL of a 112 mmol.Math.L.sup.−1 NaBH.sub.4 solution was added dropwise to a resulting mixed solution at room temperature, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) to obtain a yellow-brown silver nanoparticle sol solution; and the yellow-brown silver nanoparticle sol solution was stored in a 4° C. refrigerator and allowed to stand for 24 h to allow decomposition of residual NaBH.sub.4 for later use. [0057] Step 2: synthesis and functionalization modification of SiO.sub.2: 0.6 mL of TEOS was added dropwise to a mixed solution of 25 mL of water, 15 mL of ammonia water, and 60 mL of IPA, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) in a 35° C. water bath to allow a reaction for 30 minutes to obtain a silicon dioxide seed; then 5 mL of TEOS was added dropwise to a resulting reaction system to allow a reaction for 2 h, and a resulting product was collected through centrifugation, washed, and dried to obtain a SiO.sub.2 microsphere; in order to make a surface of SiO.sub.2 positively charged, 0.4 g of the synthesized SiO2 was ultrasonically dispersed in 200 mL of ethanol, then 2 mL of APTES was added, and a resulting mixture was stirred in a 60° C. water bath for 4 h; and a product was collected through centrifugation, repeatedly washed with ethanol, and dried to obtain APTES-SiO.sub.2. [0058] Step 3: preparation of Ag/SiO.sub.2: 0.2 g of APTES-SiO.sub.2 was dispersed in 400 mL of deionized water, then 20 mL of a 0.1 mg.Math.L.sup.−1 silver nanoparticle colloid solution (which was obtained by diluting the silver nanoparticle colloid solution obtained in step 1) was added dropwise, and a resulting mixture was vigorously stirred for 1 h (1,000 rpm to 1,400 rpm); and finally a product was collected through suction filtration, washed, and dried to obtain 1 wt % Ag/SiO.sub.2.

[0059] An amount of the silver nanoparticle colloid solution could be changed to obtain SiO.sub.2 samples loaded with Ag in different proportions. A volume ratio of the silver nanoparticle colloid solution to the deionized water was (1-10):40. In this example, 0.5 wt %, 2 wt %, and 5 wt % Ag/SiO2 samples were prepared by changing the amount of the silver nanoparticle colloid solution. [0060] Step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: 0.08 g of Ag/SiO.sub.2 was ultrasonically dispersed in 10 mL of ethanol uniformly, 0.08 g of HDA and 0.2 mL of ammonia water were added, and a resulting mixture was stirred at room temperature for uniform dispersion, during which 0.2 mL of titanium isopropoxide was added to allow a reaction for 10 minutes; the Ag/SiO.sub.2@aTiO.sub.2 with an amorphous titanium dioxide shell was collected through centrifugation, and then washed three times with each of water and ethanol; [0061] in order to prepare Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline TiO.sub.2 shell, the Ag/SiO.sub.2@aTiO.sub.2 sphere was subjected to a hydrothermal treatment as follows: Ag/SiO.sub.2@aTiO.sub.2 (0.02 g) was dispersed in a mixed solution of 20 mL of ethanol and 10 mL of water, a resulting solution was then transferred to a stainless-steel high-pressure reactor lined with PTFE, and the reactor was placed in a high-temperature oven to allow a reaction at 160° C. for 16 h; and the reactor was cooled to room temperature, and a product was collected through centrifugation, washed, dried, and finally subjected to calcination at 450° C. for 2 h in a muffle furnace to obtain Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline titanium dioxide shell.

[0062] The photocatalytic material prepared by the above method was used for removing a nitrate ion in water through photocatalytic reduction as follows: 50 mL (100 mg/L) of a low-concentration nitrate as a target pollutant and 1 mL of formic acid (0.4 mol L.sup.−1) as a sacrifice agent were added to a photocatalytic reactor; a series of catalysts were subjected to parallel contrast experiments, with a catalyst feed amount of 0.5 g.Math.L.sup.−1; a reaction system was stirred for 30 minutes before light irradiation to achieve an adsorption equilibrium; the UV lamp was turned on for irradiation, and then a temperature of the reactor was kept at about 25° C. by a circulating water bath; and a reaction was conducted for 100 minutes.

[0063] Removal effects for the nitrate were shown in FIG. 6. The ordinary TiO.sub.2 has a poor reduction effect for NO.sub.3.sup.−, and after 100 minutes of a photocatalytic reduction reaction, a removal rate is less than 40%. After TiO.sub.2 is prepared into a SiO.sub.2@TiO.sub.2 core-shell structure, a photocatalytic conversion rate of the nitrate is improved due to the improvement of the light absorption and utilization efficiency by the core-shell structure. After the Ag nanoparticle is further introduced into the Ag/SiO.sub.2@TiO.sub.2 system, photocatalytic reduction effects of Ag/SiO.sub.2@TiO.sub.2 with different silver loads for the nitrate are greatly improved, and a degree of improvement is positively correlated with the load of Ag. 5% Ag/SiO.sub.2@TiO.sub.2 has the highest photocatalytic activity and exhibits a removal rate as high as 94.2% for the nitrate.

Example 3

[0064] In this example, a preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate was provided, including the following steps: [0065] Step 1: preparation of a citrate-stabilized silver nanoparticle: 8 mL of a 40 mmol.Math.L.sup.−1 sodium citrate solution was added as a stabilizer to 100 mL of a 1 mmol.Math.L.sup.−1 silver nitrate solution; 2 mL of a 112 mmol.Math.L.sup.−1 NaBH.sub.4 solution was added dropwise to a resulting mixed solution at room temperature, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) to obtain a yellow-brown silver nanoparticle sol solution; and the yellow-brown silver nanoparticle sol solution was stored in a 4° C. refrigerator and allowed to stand for 24 h to allow decomposition of residual NaBH.sub.4 for later use. [0066] Step 2: synthesis and functionalization modification of SiO.sub.2: 0.6 mL of TEOS was added dropwise to a mixed solution of 25 mL of water, 15 mL of ammonia water, and 60 mL of IPA, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) in a 35° C. water bath to allow a reaction for 30 minutes to obtain a silicon dioxide seed; then 5 mL of TEOS was added dropwise to a resulting reaction system to allow a reaction for 2 h, and a resulting product was collected through centrifugation, washed, and dried to obtain a SiO.sub.2 microsphere; in order to make a surface of SiO.sub.2 positively charged, 0.4 g of the synthesized SiO.sub.2 was ultrasonically dispersed in 200 mL of ethanol, then 2 mL of APTES was added, and a resulting mixture was stirred in a 60° C. water bath for 4 h; and a product was collected through centrifugation, repeatedly washed with ethanol, and dried to obtain APTES-SiO.sub.2. [0067] Step 3: preparation of Ag/SiO.sub.2: 0.2 g of APTES-SiO.sub.2 was dispersed in 400 mL of deionized water, then 20 mL of a 0.1 mg.Math.L.sup.−1 silver nanoparticle colloid solution (which was obtained by diluting the silver nanoparticle colloid solution obtained in step 1) was added dropwise, and a resulting mixture was vigorously stirred for 1 h (1,000 rpm to 1,400 rpm); and finally a product was collected through suction filtration, washed, and dried to obtain 1 wt % Ag/SiO.sub.2.

[0068] An amount of the silver nanoparticle colloid solution could be changed to obtain SiO.sub.2 samples loaded with Ag in different proportions. A volume ratio of the silver nanoparticle colloid solution to the deionized water was (1-10):40. In this example, 0.5 wt %, 2 wt %, and 5 wt % Ag/SiO.sub.2 samples were prepared by changing the amount of the silver nanoparticle colloid solution. [0069] Step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: 0.08 g of Ag/SiO.sub.2 was ultrasonically dispersed in 10 mL of ethanol uniformly, 0.08 g of HDA and 0.2 mL of ammonia water were added, and a resulting mixture was stirred at room temperature for uniform dispersion, during which 0.2 mL of titanium isopropoxide was added to allow a reaction for 10 minutes; the Ag/SiO.sub.2@aTiO.sub.2 with an amorphous titanium dioxide shell was collected through centrifugation, and then washed three times with each of water and ethanol; [0070] in order to prepare Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline TiO.sub.2 shell, the Ag/SiO.sub.2@aTiO.sub.2 sphere was subjected to a hydrothermal treatment as follows: Ag/SiO.sub.2@aTiO.sub.2 (0.02 g) was dispersed in a mixed solution of 20 mL of ethanol and 10 mL of water, a resulting solution was then transferred to a stainless-steel high-pressure reactor lined with PTFE, and the reactor was placed in a high-temperature oven to allow a reaction at 160° C. for 16 h; and the reactor was cooled to room temperature, and a product was collected through centrifugation, washed, dried, and finally subjected to calcination at 450° C. for 2 h in a muffle furnace to obtain Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline titanium dioxide shell.

[0071] The photocatalytic material prepared by the above method was used to remove a nitrate ion in water through photocatalytic reduction as follows: 50 mL of a high-concentration nitrate (2,000 mg/L) as a target pollutant and 2 mL of formic acid (4 mol L.sup.−1) as a sacrifice agent were added to a photocatalytic reactor; 5% Ag/SiO.sub.2@cTiO.sub.2 was fed as a catalyst at an amount of 0.5 g.Math.L.sup.−1; a reaction system was stirred for 30 minutes before light irradiation to achieve an adsorption equilibrium; the UV lamp was turned on for irradiation, and then a temperature of the reactor was kept at about 25° C. by a circulating water bath; and a reaction was conducted for 4 h.

[0072] The changes in nitrogen-containing components and nitrogen selectivity during a nitrate removal process were shown in FIG. 7. After 4 h of a reaction, a removal rate of 5% Ag/SiO.sub.2@cTiO.sub.2 for 2,000 mg/L NO.sub.3.sup.− reaches 95.8%, and due to the rapid reduction of NO.sub.3.sup.−, NO.sub.2.sup.− accumulates as a main intermediate in large quantities at an early stage of the reaction and then is reduced. The concentration of NH.sub.4.sup.+ is low, but is always increasing, which is mainly attributed to the reduction of NO.sub.3.sup.− and NO.sub.2.sup.−. The formation of intermediates such as N.sub.2O and N.sub.2O.sub.5 during a nitrate reduction process makes the total nitrogen content slightly higher than a nitrate nitrogen content, but given the low yields of these intermediates, their influence is negligible. Due to the decrease of a reaction rate at a later stage of the reaction, a conversion rate of N.sub.2 is reduced, such that the N.sub.2 selectivity shows a trend of first increasing and then decreasing, and finally reaches 93.6%.

Example 4

[0073] In this example, a preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate was provided, including the following steps: [0074] Step 1: preparation of a citrate-stabilized silver nanoparticle: 8 mL of a 40 mmol.Math.L.sup.−1 sodium citrate solution was added as a stabilizer to 100 mL of a 1 mmol.Math.L.sup.−1 silver nitrate solution; 2 mL of a 112 mmol.Math.L.sup.−1 NaBH.sub.4 solution was added dropwise to a resulting mixed solution at room temperature, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) to obtain a yellow-brown silver nanoparticle sol solution; and the yellow-brown silver nanoparticle sol solution was stored in a 4° C. refrigerator and allowed to stand for 24 h to allow decomposition of residual NaBH.sub.4 for later use. [0075] Step 2: synthesis and functionalization modification of SiO.sub.2: 0.6 mL of TEOS was added dropwise to a mixed solution of 25 mL of water, 15 mL of ammonia water, and 60 mL of IPA, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) in a 35° C. water bath to allow a reaction for 30 minutes to obtain a silicon dioxide seed; then 5 mL of TEOS was added dropwise to a resulting reaction system to allow a reaction for 2 h, and a resulting product was collected through centrifugation, washed, and dried to obtain a SiO.sub.2 microsphere; in order to make a surface of SiO.sub.2 positively charged, 0.4 g of the synthesized SiO.sub.2 was ultrasonically dispersed in 200 mL of ethanol, then 2 mL of APTES was added, and a resulting mixture was stirred in a 60° C. water bath for 4 h; and a product was collected through centrifugation, repeatedly washed with ethanol, and dried to obtain APTES-SiO.sub.2. [0076] Step 3: preparation of Ag/SiO.sub.2: 0.2 g of APTES-SiO.sub.2 was dispersed in 400 mL of deionized water, then 20 mL of a 0.1 mg.Math.L.sup.−1 silver nanoparticle colloid solution (which was obtained by diluting the silver nanoparticle colloid solution obtained in step 1) was added dropwise, and a resulting mixture was vigorously stirred for 1 h (1,000 rpm to 1,400 rpm); and finally a product was collected through suction filtration, washed, and dried to obtain 1 wt % Ag/SiO.sub.2.

[0077] An amount of the silver nanoparticle colloid solution could be changed to obtain SiO.sub.2 samples loaded with Ag in different proportions. A volume ratio of the silver nanoparticle colloid solution to the deionized water was (1-10):40. In this example, 0.5 wt %, 2 wt %, and 5 wt % Ag/SiO.sub.2 samples were prepared by changing the amount of the silver nanoparticle colloid solution. [0078] Step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: 0.08 g of Ag/SiO.sub.2 was ultrasonically dispersed in 10 mL of ethanol uniformly, 0.08 g of HDA and 0.2 mL of ammonia water were added, and a resulting mixture was stirred at room temperature for uniform dispersion, during which 0.2 mL of titanium isopropoxide was added to allow a reaction for 10 minutes; the Ag/SiO.sub.2@aTiO.sub.2 with an amorphous titanium dioxide shell was collected through centrifugation, and then washed three times with each of water and ethanol; [0079] in order to prepare Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline TiO.sub.2 shell, the Ag/SiO.sub.2@aTiO.sub.2 sphere was subjected to a hydrothermal treatment as follows: Ag/SiO.sub.2@aTiO.sub.2 (0.02 g) was dispersed in a mixed solution of 20 mL of ethanol and 10 mL of water, a resulting solution was then transferred to a stainless-steel high-pressure reactor lined with PTFE, and the reactor was placed in a high-temperature oven to allow a reaction at 160° C. for 16 h; and the reactor was cooled to room temperature, and a product was collected through centrifugation, washed, dried, and finally subjected to calcination at 450° C. for 2 h in a muffle furnace to obtain Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline titanium dioxide shell.

[0080] The photocatalytic material prepared by the above method was used to remove a nitrate ion in water through photocatalytic reduction as follows: 50 mL of a high-concentration nitrate (2,000 mg/L) as a target pollutant and 2 mL of formic acid (4 mol L-′) as a sacrifice agent were added to a photocatalytic reactor; 5% Ag/SiO.sub.2@cTiO.sub.2 was fed as a catalyst at an amount of 0.5 g.Math.L.sup.−1; a reaction system was stirred for 30 minutes before light irradiation to achieve an adsorption equilibrium; the UV lamp was turned on for irradiation, and then a temperature of the reactor was kept at about 25° C. by a circulating water bath; a reaction was conducted for 4 h; and after the reaction was completed, the catalyst was washed and recovered for a subsequent-batch recycling experiment.

[0081] As shown in FIG. 8, after five cycles, the removal efficiency of 5% Ag/SiO.sub.2@cTiO.sub.2 for a high-concentration nitrate is not significantly decreased, and can still reach 92% or more, indicating that the material has excellent stability.

Example 5

[0082] In this example, a preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate was provided, including the following steps: [0083] Step 1: preparation of a citrate-stabilized silver nanoparticle: 8 mL of a 40 mmol.Math.L.sup.−1 sodium citrate solution was added as a stabilizer to 100 mL of a 1 mmol.Math.L.sup.−1 silver nitrate solution; 2 mL of a 112 mmol.Math.L.sup.−1 NaBH.sub.4 solution was added dropwise to a resulting mixed solution at room temperature, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) to obtain a yellow-brown silver nanoparticle sol solution; and the yellow-brown silver nanoparticle sol solution was stored in a 4° C. refrigerator and allowed to stand for 24 h to allow decomposition of residual NaBH.sub.4 for later use. [0084] Step 2: synthesis and functionalization modification of SiO.sub.2: 0.6 mL of TEOS was added dropwise to a mixed solution of 25 mL of water, 15 mL of ammonia water, and 60 mL of IPA, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) in a 35° C. water bath to allow a reaction for 30 minutes to obtain a silicon dioxide seed; then 5 mL of TEOS was added dropwise to a resulting reaction system to allow a reaction for 2 h, and a resulting product was collected through centrifugation, washed, and dried to obtain a SiO.sub.2 microsphere; in order to make a surface of SiO.sub.2 positively charged, 0.4 g of the synthesized SiO.sub.2 was ultrasonically dispersed in 200 mL of ethanol, then 2 mL of APTES was added, and a resulting mixture was stirred in a 60° C. water bath for 4 h; and a product was collected through centrifugation, repeatedly washed with ethanol, and dried to obtain APTES-SiO.sub.2. [0085] Step 3: preparation of Ag/SiO.sub.2: 0.2 g of APTES-SiO.sub.2 was dispersed in 400 mL of deionized water, then 20 mL of a 0.1 mg.Math.L.sup.−1 silver nanoparticle colloid solution (which was obtained by diluting the silver nanoparticle colloid solution obtained in step 1) was added dropwise, and a resulting mixture was vigorously stirred for 1 h (1,000 rpm to 1,400 rpm); and finally a product was collected through suction filtration, washed, and dried to obtain 1 wt % Ag/SiO.sub.2.

[0086] An amount of the silver nanoparticle colloid solution could be changed to obtain SiO.sub.2 samples loaded with Ag in different proportions. A volume ratio of the silver nanoparticle colloid solution to the deionized water was (1-10):40. In this example, 0.5 wt %, 2 wt %, and 5 wt % Ag/SiO.sub.2 samples were prepared by changing the amount of the silver nanoparticle colloid solution. [0087] Step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: 0.08 g of Ag/SiO.sub.2 was ultrasonically dispersed in 10 mL of ethanol uniformly, 0.08 g of HDA and 0.2 mL of ammonia water were added, and a resulting mixture was stirred at room temperature for uniform dispersion, during which 0.2 mL of titanium isopropoxide was added to allow a reaction for 10 minutes; the Ag/SiO.sub.2@aTiO.sub.2 with an amorphous titanium dioxide shell was collected through centrifugation, and then washed three times with each of water and ethanol; [0088] in order to prepare Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline TiO.sub.2 shell, the Ag/SiO.sub.2@aTiO.sub.2 sphere was subjected to a hydrothermal treatment as follows: Ag/SiO.sub.2@aTiO.sub.2 (0.02 g) was dispersed in a mixed solution of 20 mL of ethanol and 10 mL of water, a resulting solution was then transferred to a stainless-steel high-pressure reactor lined with PTFE, and the reactor was placed in a high-temperature oven to allow a reaction at 160° C. for 16 h; and the reactor was cooled to room temperature, and a product was collected through centrifugation, washed, dried, and finally subjected to calcination at 450° C. for 2 h in a muffle furnace to obtain Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline titanium dioxide shell.

[0089] The photocatalytic material prepared by the above method was used to remove a nitrate ion in water through photocatalytic reduction as follows: 50 mL of a high-concentration nitrate (2,000 mg/L) as a target pollutant and 2 mL of formic acid (4 mol L-′) as a sacrifice agent were added to a photocatalytic reactor, and 4 wt % to 10 wt % NaCl was added in parallel to the photocatalytic reactor; 5% Ag/SiO.sub.2@cTiO.sub.2 was fed as a catalyst at an amount of 0.5 g.Math.L.sup.−1; a reaction system was stirred for 30 minutes before light irradiation to achieve an adsorption equilibrium; the UV lamp was turned on for irradiation, and then a temperature of the reactor was kept at about 25° C. by a circulating water bath; and a reaction was conducted for 5.3 h.

[0090] Nitrate removal effects under the interference of a high-concentration chloride ion were shown in FIG. 9. Although the high-concentration chloride ion inhibits a photocatalytic reduction rate of the nitrate, but when the reaction time is extended to 5.3 h, a nitrate removal rate of 92% or more can still be achieved. In addition, XPS spectra before and after the reaction (FIG. 10) show that Cl.sup.− does not contaminate a surface of the catalyst to inactivate the catalyst.

Example 6

[0091] In this example, a preparation method of a photocatalytic material for efficient photocatalytic removal of a high-concentration nitrate was provided, including the following steps: [0092] Step 1: preparation of a citrate-stabilized silver nanoparticle: 8 mL of a 40 mmol.Math.L.sup.−1 sodium citrate solution was added as a stabilizer to 100 mL of a 1 mmol.Math.L.sup.−1 silver nitrate solution; 2 mL of a 112 mmol.Math.L.sup.−1 NaBH.sub.4 solution was added dropwise to a resulting mixed solution at room temperature, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) to obtain a yellow-brown silver nanoparticle sol solution; and the yellow-brown silver nanoparticle sol solution was stored in a 4° C. refrigerator and allowed to stand for 24 h to allow decomposition of residual NaBH.sub.4 for later use. [0093] Step 2: synthesis and functionalization modification of SiO.sub.2: 0.6 mL of TEOS was added dropwise to a mixed solution of 25 mL of water, 15 mL of ammonia water, and 60 mL of IPA, and a resulting mixture was vigorously stirred (1,000 rpm to 1,400 rpm) in a 40° C. water bath to allow a reaction for 30 minutes to obtain a silicon dioxide seed; then 5 mL of TEOS was added dropwise to a resulting reaction system to allow a reaction for 2 h, and a resulting product was collected through centrifugation, washed, and dried to obtain a SiO.sub.2 microsphere; in order to make a surface of SiO.sub.2 positively charged, 0.4 g of the synthesized SiO.sub.2 was ultrasonically dispersed in 200 mL of ethanol, then 2 mL of APTES was added, and a resulting mixture was stirred in a 50° C. water bath for 4 h; and a product was collected through centrifugation, repeatedly washed with ethanol, and dried to obtain APTES-SiO.sub.2. [0094] Step 3: preparation of Ag/SiO.sub.2: 0.2 g of APTES-SiO.sub.2 was dispersed in 400 mL of deionized water, then 20 mL of a 0.1 mg.Math.L.sup.−1 silver nanoparticle colloid solution (which was obtained by diluting the silver nanoparticle colloid solution obtained in step 1) was added dropwise, and a resulting mixture was vigorously stirred for 1 h (1,000 rpm to 1,400 rpm); and finally a product was collected through suction filtration, washed, and dried to obtain 1 wt % Ag/SiO.sub.2.

[0095] An amount of the silver nanoparticle colloid solution could be changed to obtain SiO.sub.2 samples loaded with Ag in different proportions. A volume ratio of the silver nanoparticle colloid solution to the deionized water was (1-10):40. In this example, 0.5 wt %, 2 wt %, and 5 wt % Ag/SiO.sub.2 samples were prepared by changing the amount of the silver nanoparticle colloid solution. [0096] Step 4: preparation of an Ag/SiO.sub.2@cTiO.sub.2 core-shell structure: 0.08 g of Ag/SiO.sub.2 was ultrasonically dispersed in 10 mL of ethanol uniformly, 0.08 g of HDA and 0.2 mL of ammonia water were added, and a resulting mixture was stirred at room temperature for uniform dispersion, during which 0.2 mL of titanium isopropoxide was added to allow a reaction for 10 minutes; the Ag/SiO.sub.2@aTiO.sub.2 with an amorphous titanium dioxide shell was collected through centrifugation, and then washed three times with each of water and ethanol; [0097] in order to prepare Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline TiO.sub.2 shell, the Ag/SiO.sub.2@aTiO.sub.2 sphere was subjected to a hydrothermal treatment as follows: Ag/SiO.sub.2@aTiO.sub.2 (0.02 g) was dispersed in a mixed solution of 20 mL of ethanol and 10 mL of water, a resulting solution was then transferred to a stainless-steel high-pressure reactor lined with PTFE, and the reactor was placed in a high-temperature oven to allow a reaction at 140° C. for 12 h; and the reactor was cooled to room temperature, and a product was collected through centrifugation, washed, dried, and finally subjected to calcination at 500° C. for 2 h in a muffle furnace to obtain Ag/SiO.sub.2@cTiO.sub.2 with a mesoporous structure and a crystalline titanium dioxide shell.

[0098] In summary, compared with the traditional titanium dioxide, the Ag/SiO.sub.2@cTiO.sub.2 material prepared by the present disclosure can remove a high-concentration nitrate through efficient photocatalytic reduction, and can still retain high photocatalytic activity and stability even when the nitrate coexists with a high-concentration chloride ion.