High-efficiency visible-light catalytic material and preparation method and application thereof

Abstract

A high-efficiency visible-light catalytic material, a preparation method and an application thereof are provided by the present application, relating to the technical field of photocatalytic materials. The present application prepares photocatalytic material Ag@AgCl/CA by compounding Ag@AgCl and calcium alginate gel, and the prepared photocatalytic material is shaped as small particles. The photocatalytic material Ag@AgCl/CA is used to degrade tetracycline antibiotics.

Claims

1. A preparation method of a high-efficiency visible-light catalytic material, comprising following steps: (1) mixing cationic emulsifier and sodium alginate in a solution, followed by ultrasonically dispersing; (2) adding AgNO.sub.3, Ca(NO.sub.3).sub.2 and NaCl into a mixed solution prepared in the step (1) in sequence, followed by stirring, standing, filtering and collecting precipitate; and (3) adding the precipitate obtained in the step (2) into water, then irradiating with an ultraviolet lamp, filtering, washing and freeze-drying to obtain Ag @AgCl/CA as the high-efficiency visible-light catalytic material; wherein the cationic emulsifier is cetyltrimethyl ammonium bromide.

2. The preparation method according to claim 1, wherein a duration for the standing in the step (2) is 4-8 h.

3. The preparation method according to claim 1, wherein a mass ratio of the sodium alginate to the AgNO.sub.3, the Ca(NO.sub.3).sub.2 and the NaCl is 1:(2-3.5):4:(0.5-2).

4. The preparation method according to claim 1, wherein in the step (3), a power for the irradiating with the ultraviolet lamp is 10 W, and a duration is 30 min.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) To illustrate more clearly the technical schemes in the embodiments of the present application or in the prior art, a brief description of the accompanying drawings to be used in the embodiments is given below. It is obvious that the accompanying drawings in the following description are only some embodiments of the present application and that other accompanying drawings are available to those of ordinary skill in the art without any creative effort.

(2) FIG. 1A shows a picture of scanning electron microscope of a photocatalytic material Ag@AgCl/CA prepared in Embodiment 1 at a magnification of 2000.

(3) FIG. 1B shows a picture of scanning electron microscope of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1 at a magnification of 10000.

(4) FIG. 1C shows a picture of scanning electron microscope of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1 at a magnification of 20000.

(5) FIG. 2 shows a picture of transmission electron microscope of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(6) FIG. 3 shows energy dispersive spectrometer (EDS) spectra of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(7) FIG. 4 is a surface mapping of main elements of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(8) FIG. 5 shows an infrared spectrum of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(9) FIG. 6A shows N.sub.2 adsorption-desorption isotherms of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(10) FIG. 6B is a diagram illustrating pore size distribution of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(11) FIG. 7A is a diagram showing transient photocurrent response of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(12) FIG. 7B is a diagram showing electrochemical impedance spectrum (EIS) of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(13) FIG. 8 is a potential diagram of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(14) FIG. 9 shows ultraviolet-visible (UV-Vis) diffuse reflection spectroscopy (DRS) diagram of Ag@AgCl/CA prepared in Embodiment 1 and Ag@AgCl.

(15) FIG. 10 shows adsorption spectra of Ag@AgCl/CA prepared in Embodiment 1 for oxytetracycline (OTC) photodegradation under visible-light.

(16) FIG. 11 shows a recycling stability test of Ag@AgCl/CA prepared in Embodiment 1 for photocatalytic OTC degradation.

(17) FIG. 12 shows a process of a preparation method of a high-efficiency visible-light catalytic material according to the present application.

DETAILED DESCRIPTION OF THE EMBODIMENTS

(18) Various exemplary embodiments of the present application are now described in detail, and this detailed description should not be considered a limitation of the present application, but should be understood as a more detailed description of certain aspects, features and embodiments of the present application.

(19) It is to be understood that the terms described in the present application are intended to describe particular embodiments only and are not intended to limit the present application. Further, with respect to the range of values in the present application, it is to be understood that each intermediate value between the upper and lower limits of the range is also specifically disclosed. Each smaller range between any stated value or intermediate value within a stated range and any other stated value or intermediate value within a stated range is also included in the present application. The upper and lower limits of these smaller ranges may be independently included or excluded from the scope.

(20) Unless otherwise specified, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this present application relates. Although the present application only describes the preferred methods and materials, any methods and materials similar or equivalent to those described herein can also be used in the practice or testing of the present application. All documents mentioned in this specification are incorporated by reference to disclose and describe methods and/or materials related to the documents. In case of conflict with any incorporated document, the contents of this specification shall prevail.

(21) Without departing from the scope or spirit of the present application, a variety of improvements and variations to specific embodiments of the specification of the present application are possible, as will be apparent to those skilled in the art. Other embodiments obtained from the specification of the present application are obvious to the skilled person. The specification and embodiments of the present application are only exemplary.

(22) The terms comprising, including, having and containing used in this specification are all open terms, which means including but not limited to.

Embodiment 1

(23) A preparation method of an efficient visible-light catalytic material Ag @AgCl/CA includes following steps as shown in FIG. 12: step 1, mixing cationic emulsifier and sodium alginate in a solution, followed by ultrasonically dispersing; step 2, adding AgNO.sub.3, Ca(NO.sub.3).sub.2 and NaCl into a mixed solution prepared in the step 1 in sequence, followed by stirring, standing, filtering and collecting precipitate; and step 3, adding the precipitate obtained in the step 2 into water, then irradiating with an ultraviolet lamp, filtering, washing and freeze-drying to obtain Ag @AgCl/CA as the high-efficiency visible-light catalytic material.

(24) Specifically, the preparation method includes: (1) 100 milliliters (mL) of 2 grams per liter (g/L) sodium alginate (SA) solution is added with 16 mL of cationic emulsifier cetyltrimethyl ammonium bromide (CTAB) with the concentration of 10 g/L, and dispersed by ultrasonic for 30 minutes (min), so that CTAB and SA solution are fully mixed; (2) under magnetic stirring, 12 mL of 50 g/L AgNO.sub.3 solution is slowly dropped into the reaction system of step (1), and after the dropping is finished, magnetic stirring is continued for 15 min, and then 40 mL of 20 g/L Ca(NO.sub.3).sub.2 solution is slowly dropped into the obtained mixed suspension; the magnetic stirring is continued for another 15 min, then 10 mL of 20 g/L NaCl solution is slowly drop-added, and the stirring is stopped after 30 min, followed by standing for 4 h; the reaction system is filtered with a double gauze, and the obtained small particle precipitate is washed with deionized water for 5 times; (3) the small particle precipitate obtained in step (2) is added into a 250 mL triangular flask, then the triangular flask is added with 50 mL deionized water, and placed in a 10 Watts (W) ultraviolet lamp for 30 min under magnetic stirring; the particles filtered by double gauze are washed with deionized water for 3 times, and vacuum freeze-dried to obtain the Ag@AgCl/CA photocatalytic material; and 0.2 g of the Ag@AgCl/CA photocatalytic material is added into a 100 mL triangular flask, then 60 mL of 10 milligrams per liter (mg.Math.L.sup.1) oxytetracycline (OTC) solution is added, and the initial pH value is adjusted to 6.0, with the temperature being controlled at 40 degrees Celsius ( C.), followed by stirring in the dark for 30 min to achieve adsorption-desorption equilibrium; the triangular flask is then placed in a xenon lamp with 350 W visible-light (filtered by a 420 nanometers (nm) ultraviolet cut-off filter) for catalytic degradation of 10-30 min under magnetic stirring.

(25) FIG. 1A, FIG. 1B, FIG. 1C and FIG. 2 are the morphologies of the Ag @AgCl/CA photocatalytic material prepared in Embodiment 1 as observed by high-resolution field emission scanning electron microscopy (SEM) and transmission electron microscopy (TEM), respectively. FIG. 1A, FIG. 1B and FIG. 1C are SEM images of Ag@AgCl/CA photocatalytic material with different magnifications, while FIG. 2 is a transmission electron microscope image of Ag@AgCl/CA photocatalytic material.

(26) The calcium alginate (CA) gel structure is loaded with a large number of irregularly shaped Ag@AgCl particles, which partially overlap and accumulate in clusters. The Ag@AgCl particles are sphere-like with a non-uniform particle size of 50-100 nm, indicating that the Ag@AgCl particles are successfully loaded within the Ca.sup.2+ cross-linked voids and that the gel grid-like structure serves as a spacer to effectively partition the clustered Ag@AgCl particles, which to a certain extent facilitates the adsorption and rapid degradation of OTC and effectively improves the photocatalytic performance of the composite material.

(27) FIG. 3 and FIG. 4 are respectively the energy dispersive spectrometer (EDS) diagram and surface mapping of main elements of the photocatalytic material Ag @AgCl/CA prepared in Embodiment 1.

(28) The results show that the sample contains elements such as Ag, Cl, C, O, N, Ca and Br, among which the mass concentration of element Ag is larger, second only to that of element C. The concentration of Ag atoms is also larger, second only to that of C and O, while the concentration of Cl atoms is about half of that of Ag atoms, i.e. Ag:AgCl=1:1, indicating that there are roughly nano-Ag particles attached to the surface of each AgCl particle. Moreover, the presence of some N and Br atoms in the material indicates that the prepared catalytic material contains a small amount of AgBr impurity particles and CTAB cationic components, while the small amount of AgBr particles also synergizes with the catalytic degradation of the pollutants by Ag@AgCl.

(29) FIG. 5 shows an infrared spectrum of the photocatalytic material Ag @AgCl/CA prepared in Embodiment 1.

(30) As can be seen from the FIG. 5, the adsorption peak at 1,030 cm.sup.1 is attributed to the COC telescopic vibration adsorption peak of the epoxy group, the peaks appearing at 1,597 cm.sup.1 and 1,403 cm.sup.1 correspond to the telescopic vibration peak of the CO of COOH and the bending vibration peak of OH in SA, respectively; the adsorption peak at 2,915 cm.sup.1 is a methyl (CH.sub.3) telescopic vibration and the adsorption peak at 2,851 cm.sup.1 is a manifestation of the telescopic vibration of the methylene (CH.sub.2) of the alkane chain of the CTAB molecule; the composite materials all show a strong adsorption peak around 3,375 cm.sup.1, which is a telescopic vibration of the joined hydroxyl group (OH), i.e. a telescopic vibration of the OH bond of the oxygen-containing functional group.

(31) FIG. 6A and FIG. 6B show the N.sub.2 adsorption-desorption isotherm and the pore size distribution of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1.

(32) The isotherms are in accordance with Class IV isotherms, indicating that the composite material has a mesoporous (mesopore) structure, which is conducive to the contact between the catalyst and the OTC, as well as to the adsorption of visible-light, therefore reducing the electron-hole combination and improving the photocatalytic degradation performance of the composite material. The material has a specific surface area of 0.96553 m.sup.2/g, an average pore size of 21.311 nm and a pore size distribution between 2 and 100 nm. A certain amount of catalyst has a limited surface area, and the catalytic degradation effect is mainly determined by the amount of pollutants adsorbed on the catalyst surface. According to the photocatalytic oxidation mechanism, the compounding of photogenerated electrons and holes on the catalyst surface is completed in less than 10.sup.9 seconds (s), whereas the rate at which carriers are captured is relatively slow, usually taking 10.sup.8-10.sup.7 s. Therefore, only pollutants adsorbed on the catalyst surface have the possibility to obtain highly active electrons to react with holes.

(33) FIG. 7A shows the transient photocurrent response characteristics of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1 at each switched-on and shaded light.

(34) It can be seen from the drawing that the Ag@AgCl/CA composite material produces a fast and stable photocurrent with good reversibility under visible-light irradiation, suggesting that the composite material has strong photoresponsiveness, good photocurrent response performance, high photogenerated electronic transfer efficiency and high separation efficiency of electron-hole pairs, thus indicating that the prepared composite photocatalytic material has high photocatalytic activity.

(35) FIG. 7B shows the electrochemical impedance spectrum (EIS) of the photocatalytic material Ag@AgCl/CA prepared in Embodiment 1, and the characterization results of the EIS indicate that the radius of the arc is relatively large in the absence of light, and the radius of the arc decreases significantly with light irradiation. Therefore, it is evident that the prepared composite material photocatalytic material exhibits good photocatalytic performance with small photogenerated electron transfer resistance and low photogenerated electron-hole complexation rate under light radiation.

(36) FIG. 8 shows that the zeta potentials of the Ag@AgCl/CA photocatalytic materials prepared in Embodiment 1 at pH 4, 5, 6, 7 and 8 are respectively 30.1 millivolts (mV), 32.7 mV, 34.8 mV, 30.9 mV and 43.5 mV, indicating that the catalytic materials are negatively charged on the surface of the catalytic materials at pH 4-8, at which time there is a repulsive effect between the particles of the catalytic materials, resulting in a potential resistance effect, suggesting that the catalytic material has a strong stability. Also, studies have shown that when the initial pH of the solution is over 7, Ag.sup.+ combines with the hydroxide in the solution to form a precipitate that discolours the solution, so the catalyst is better used under acidic conditions.

(37) FIG. 9 shows ultraviolet-visible (UV-Vis) diffuse reflection spectroscopy (DRS) diagram of Ag@AgCl/CA prepared in Embodiment 1 and Ag@AgCl. As shown in FIG. 9, the Ag@AgCl/CA catalytic material not only has a strong adsorption in the UV region below 350 nm, but also has a relatively strong adsorption in the visible region range from 500 to 650 nm. The indirect energy band gap of AgCl is reported to be around 3.25 electron volts (eV), and AgCl has almost no adsorption properties in the 400-800 nm range, except for the adsorption band in the UV region. Consequently, the catalytic material has strong adsorption properties in the visible region attributed to the resonance adsorption band generated by the surface plasmon resonance (SPR) effect of Ag nanoparticles.

(38) FIG. 10 shows the adsorption curves of the Ag@AgCl/CA catalytic material prepared in Embodiment 1 for the photocatalytic degradation of OTC at 40 C. with an initial pH of the solution of 6 at different time. The OTC has 2 obvious adsorption peaks at 275 nm and 355 nm respectively. After 30 min of adsorption in the dark, the adsorption peaks decrease substantially. After 6 min of irradiation, the adsorption peak at 275 nm disappears, while the adsorption peak at 355 nm decreases significantly. With the extension of irradiation time, the absorbance at 355 nm gradually decreases and the adsorption peak is slightly blue-shifted.

(39) The degradation curves of the Ag@AgCl/CA catalytic material prepared in Embodiment 1 cycled 5 times are shown in FIG. 11. The activity of the photocatalytic material shows no significant change, and the degradation rate of the OTC is still greater than 90.0%, indicating that the catalytic material has good photocatalytic stability and reusability, and has great potential for application as a visible photocatalyst in practical production.

(40) The above-mentioned embodiments only describe the preferred mode of the present application, and do not limit the scope of the present application. Under the premise of not departing from the design spirit of the present application, various modifications and improvements made by ordinary technicians in the field to the technical scheme of the present application shall fall within the protection scope determined by the claims of the present application.