KR20230102049A - Manufacturing method of rutheniumdioxide-silver complex - Google Patents

Abstract

The present invention relates to a method for producing a multifunctional ruthenium dioxide-silver (RuO ₂ @Ag) composite by reacting monodisperse ruthenium dioxide particles with Ag.
According to the present invention, monodisperse RuO ₂ particles can be easily prepared in one-pot without a complicated process at low cost using inexpensive commercial precursor reagents, and a composite in which silver is bonded can be uniformly prepared using the same.

Description

Manufacturing method of ruthenium dioxide-silver complex {Manufacturing method of rutheniumdioxide-silver complex}

The present invention relates to a method for producing a multifunctional ruthenium dioxide-silver (RuO ₂ @Ag) composite by reacting monodisperse ruthenium dioxide particles with Ag.

According to the present invention, monodisperse RuO ₂ particles can be easily prepared in one-pot without a complicated process at low cost using an inexpensive commercial precursor reagent, and a composite in which metallic silver (Ag) is bonded can be uniformly prepared using the same.

Nano metal oxide particle technology expands into new technology areas through organic research on physics, materials, and chemical properties in the fields of electronics, information, energy, space, communication, environment, and life sciences, thereby minimizing size and energy consumption. It is a useful technology that enables high value-added economics because it can realize the best performance while doing so.

In particular, nano metal oxide particles have new optical, electrical, and magnetic properties due to their semiconductor properties that are different from those of bulk metal oxide particles, and have a different band gap due to quantum size effects depending on their size or shape. Accordingly, the physical and chemical properties change. In addition, it is a material that is expected to have many applications due to its unique thermal and chemical stability.

Among them, RuO ₂ is a black solid metal oxide that crystallizes into a rutile structure and is a compound used in various chemical catalyst, electric, and electronic device fields. This classical synthesis of RuO ₂ particles requires a large amount of energy due to the high reaction temperature of up to 1000 °C. In addition, Ru, a component, is a rare metal with various oxidation numbers of 2, 3, 4, 5, 7, and 8, and belongs to the platinum group. Due to its high price, it is difficult to apply it as a nanomaterial in the advanced electric and electronic industries.

Nevertheless, RuO ₂ stands out in the field of super capacitors by showing a high capacitance of 650 F/g with high charge transfer and storage capabilities compared to other materials. RuO ₂ is known for many applications as photocatalysts, batteries, and resistors along with supercapacitors. Meanwhile, in order to adjust the electrical conductivity of RuO ₂ , Ag metal powder may be mixed and used.

Republic of Korea Patent No. 10-2177595

Conventionally in RuO ₂ The method of mixing Ag uses simple mechanical mixing, so it is difficult to use it as an electronic material because uniform mixing is not achieved.

Accordingly, an object of the present invention is to provide a method for preparing a composite in which Ag metal is uniformly bonded to submicron-sized monodisperse RuO ₂ particles.

In order to achieve the above object, the present invention

(1) dispersing monodisperse RuO ₂ in deionized water in container 1;

(2) dissolving a silver (Ag) precursor in deionized water in container 2, adding a reducing agent and stirring;

(3) preparing an alcohol solution of a surfactant in container 3;

(4) adding the solution in container 2 and the solution in container 3 to the solution in container 1 and stirring in an ice bath, and

(5) Provides a method for preparing a ruthenium dioxide-silver (RuO ₂ @Ag) composite comprising the step of subjecting the solution of step (4) to a reflux reaction.

The present invention has an effect of providing a method for easily preparing a RuO ₂ @Ag composite having various functions by reacting a relatively inexpensive silver (Ag) precursor with monodisperse RuO ₂ particles. The present invention has the effect of preparing a composite in which Ag metal of uniform size is bonded to monodisperse RuO ₂ .

The monodisperse RuO ₂ used in the preparation of the RuO ₂ @Ag composite according to the present invention has the advantages of relatively uniform particle size, spherical particle populations, and clear boundaries between the particle populations. Since there is no aggregation, when a RuO ₂ @Ag composite is prepared using this, monodisperse uniform particles can be prepared. In addition, since the ratio of ruthenium dioxide and silver (Ag) is uniform, physical properties are uniform when used in a resistor or the like.

1 shows a FE-SEM image of monodisperse RuO ₂ particles prepared using an organic solvent.
2 shows a FE-SEM image of monodisperse RuO ₂ particles prepared using water as a solvent.
3 shows the submicron-sized monodisperse RuO ₂ particles (a), the multifunctional RuO ₂ @Ag particles (b) with Ag attached to the surface of the submicron-sized monodisperse RuO ₂ particles, and the heat treatment process at 300° C. for 2 hours. It shows the FE-SEM image of multifunctional RuO ₂ @Ag particles (c).
4 shows submicron-sized monodisperse RuO ₂ particles (a), multifunctional RuO ₂ @Ag particles (b) with Ag attached to the surface of submicron-sized monodisperse RuO ₂ particles, and heat treatment process at 300° C. for 2 hours. It shows an XRD image of multifunctional RuO ₂ @Ag particles (c) that have undergone

Hereinafter, the present invention will be described in detail. The terms or words used in this specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventors can properly define the concept of terms in order to best explain their invention. Based on the principle, it should be interpreted as a meaning and concept consistent with the technical idea of the present invention.

RuO ₂ shows high capacitance and is highly likely to be used in the field of supercapacitors, and is a material that can be used in many applications such as other photocatalysts, batteries, and resistors.

Recently, efforts have been made to attach Ag nanoparticles having high optical and electrical properties to these ruthenium dioxide particles and use them as photocatalysts, photovoltaic power generation fields, and electrical and electronic devices. For example, ruthenium dioxide can be used to make a paste for resistance materials to be applied to chip termination, which is a 5G communication component. At this time, silver (Ag) powder can be mixed to adjust electrical conductivity.

In this way, a simple mixing method has been conventionally used to mix silver powder with ruthenium dioxide. In this case, the homogeneity of the resulting mixture is not good, which is a problem.

Accordingly, the present invention has completed the present invention as a result of efforts to provide a method of using the ruthenium dioxide-silver (RuO ₂ @Ag) composite so as not to cause a homogeneity problem and using it as a resistance material.

In addition, the present invention is ruthenium dioxide used in the manufacture of a ruthenium dioxide-silver (RuO ₂ @Ag) composite, and when monodisperse ruthenium dioxide having a uniform size and a submicron diameter is used, monodisperse ruthenium dioxide- A silver (RuO ₂ @Ag) composite can be prepared.

the present invention

(1) dispersing monodisperse RuO ₂ in deionized water in container 1;

(2) dissolving a silver (Ag) precursor in deionized water in container 2, then adding a reducing agent and stirring;

(3) preparing an alcohol solution of a surfactant in container 3;

(4) adding the solutions of containers 2 and 3 to the solution in container 1 and stirring in an ice bath; and

(5) It provides a method for producing a ruthenium dioxide-silver (RuO ₂ @Ag) composite comprising the step of refluxing the solution of step (4).

The step (4) may consist of adding the solution in container 1 to the solution in container 2 and stirring in an ice bath, followed by adding the solution in container 3 and stirring in an ice bath.

The step (1) may be a step of dispersing in 30-100 mL, preferably 40-70 mL, of deionized water per 1 g of monodisperse RuO ₂ particles, and ultrasonic waves may be used to facilitate the dispersion.

In the present invention, the silver (Ag) precursor can be used without limitation as long as it is reduced to form silver, and includes silver nitrate, silver nitrite, silver acetate, silver perchlorate, or a mixture thereof, and preferably silver nitrate.

Step (2) is a silver precursor It may be a step of dissolving in 100-500mL of deionized water per 1g, and ultrasonic waves may be used to facilitate dissolution by adding a reducing agent. The silver precursor may be used in an amount of 0.05-0.2 g per 1 g of RuO ₂ . When less than 0.05 g of silver precursor is used for RuO ₂ , the role of Ag in the RuO ₂ @Ag complex is insignificant, and when it is used in excess of 0.2 g, it is difficult to prepare the RuO ₂ @Ag complex due to surface aggregation of Ag particles.

In the present invention, the reducing agent may be selected from the group consisting of NH ₄ OH, NaBH ₄ , LiBH ₄ , LiAlH ₄ and ascorbic acid, and is preferably NH ₄ OH. The reducing agent is a silver precursor When 2.0 to 2.2 mol is used per 1 mol, reduced silver is obtained from the silver precursor, and a RuO ₂ @Ag complex can be obtained using this.

As the surfactant, any material that serves to control the size of Ag particles reduced on the surface can be used, and is preferably polyvinylpyrrolidone (PVP). The surfactant may be used in an amount of 0.05-0.3g per 1g of RuO ₂ . Ag particles having a uniform size can be produced when the surfactant is used in the above amount.

The alcohol may be methanol, ethanol, propanol, isopropanol, etc., and is preferably ethanol. 200-700mL of alcohol can be used for 1g of surfactant.

In the step (4), stirring in an ice bath for 20 minutes to 2 hours may facilitate mixing of the reactants before the subsequent reflux step.

The step (5) may be a step of refluxing at 60-90 ° C. for 1-10 hours. As the reflux reaction proceeds at the above temperature and time, a RuO ₂ @Ag composite in which Ag is attached to the surface of RuO ₂ may be obtained.

The ruthenium dioxide-Ag (RuO ₂ @Ag) composite prepared by the method of the present invention may be heat-treated at 250° C. or more to prepare a ruthenium dioxide-Ag (RuO ₂ @Ag) composite having increased crystallinity of ruthenium dioxide.

It can be seen that the RuO ₂ of the RuO ₂ @Ag composite of the present invention is stable without any change in size or shape before and after Ag is attached, and Ag attached to RuO ₂ has a size of 40-100 nm. The RuO ₂ @Ag composite prepared as described above is stable without Ag dropping or deformation of RuO ₂ even when subjected to heat treatment at 300° C., and the crystallinity of RuO ₂ may increase to have a rutile structure. Therefore, it can be stably used in various elements requiring heat treatment.

When the monodisperse RuO ₂ of the present invention is prepared by hydrothermal synthesis or solvothermal synthesis in water or a polar organic solvent, it is prepared in a spherical monodisperse form having a uniform submicron size, and in this case, monodisperse ruthenium dioxide- It is easy to prepare the silver composite.

The monodisperse ruthenium dioxide for preparing the ruthenium dioxide-silver composite of the present invention is

(a) dissolving a ruthenium precursor in water or a polar organic solvent, adding an oxidizing agent and an alkaline compound and stirring; and

(b) refluxing the solution.

The present invention can obtain submicron-sized spherical monodisperse RuO ₂ particles by using cost-saving metal precursors and eco-friendly solvents by reducing complex processes and using inexpensive commercial precursor reagents and by using additives that form monodisperse particles. there is.

In the step (a), when a surfactant is added and stirred, monodisperse particles may be prepared in a spherical shape with a relatively uniform size.

According to one embodiment of the present invention

The step (a) is

(a-1) dissolving the ruthenium precursor in water and adding an oxidizing agent, and

(a-2) may include adding an alkaline compound to the step (a-1) solution and stirring.

According to one embodiment of the present invention

The step (a) is

(a-3) dissolving a ruthenium precursor in a polar organic solvent, adding an oxidizing agent and stirring;

(a-4) adding a surfactant to the solution of step (a-3) and stirring; and

(a-5) may include adding an alkaline compound dissolved in a polar organic solvent to the solution of step (a-4) and stirring the solution.

The step (a) may preferably be carried out at room temperature. The present invention has the advantage that additional costs such as heating or cooling are not added by performing step (a) at room temperature.

The ruthenium precursor may be a ruthenium salt compound, preferably RuCl ₃ , RuI ₃ or a hydrate thereof. The present invention has the advantage of economically preparing monodisperse RuO ₂ particles by using a relatively inexpensive ruthenium salt as a Ru raw material for preparing RuO ₂ .

In the present invention, by using water in step (a-1), monodisperse ruthenium dioxide can be economically produced in a large amount. In this case, 20 to 80 mL of water, preferably 30 to 50 mL, may be used for 1 g of the ruthenium precursor.

In the present invention, an environmentally friendly organic solvent may be used as the polar organic solvent in steps (a-3) and (a-5), and preferably ethylene glycol, diethylene glycol, and the like may be used. The polar organic solvents in the steps (a-3) and (a-5) may be the same or different, and are preferably the same. Ethylene glycol has a particularly wide liquid range from -13 to 198 ℃, so it has the advantage of being able to carry out a reflux reaction at a high temperature over 100 ℃, and when a surfactant is added, the growth rate of RuO ₂ monodispersion is controlled to control the particle size and has the advantage of being able to control aggregation. For the above effect, the polar organic solvent may be preferably used in an amount of 50-100mL per 1g of the ruthenium precursor.

The present invention uses an oxidizing agent to oxidize ruthenium to make tetravalent ruthenium, and the oxidizing agent is preferably hydrogen peroxide (H ₂ O ₂ ). Hydrogen peroxide is an environmentally friendly oxidizing agent and is useful for obtaining pure monodisperse RuO ₂ particles because there are no by-products other than water after use. When the hydrogen peroxide is preferably used in an amount of 0.2-2mL, preferably 0.5-1.5mL, per 1g of the ruthenium precursor, pure monodisperse RuO ₂ particles can be obtained. It is preferable to add the hydrogen peroxide slowly, and it may be stirred for 10 minutes to 2 hours for sufficient oxidation of Ru.

In the present invention, a surfactant can be used to prepare more uniform monodisperse ruthenium dioxide, and the surfactant can preferably be polyvinyl pyrrolidone, and 0.3-0.7g per 1g of the ruthenium precursor is used. In this case, uniform monodisperse RuO ₂ particles can be obtained.

The step of adding and stirring the surfactant of step (a-4) may be stirred for 10 minutes to 60 minutes to form monodisperse particles.

The alkaline compound for the production of monodisperse ruthenium dioxide may preferably be NaOH or KOH. The alkaline compound may be added by dissolving in water or an organic solvent, and uniform monodisperse RuO ₂ particles may be obtained when 0.6-5 g per 1 g of the ruthenium precursor is used. The step of adding and stirring the alkaline compound may preferably be 20 minutes to 5 hours.

The step (b) may be a step of refluxing at 70 to 200 ℃.

In the step (b), when water is refluxed at 70 to 110 ° C. as a solvent, monodisperse ruthenium dioxide can be produced in a large amount.

In the step (b), when water or an organic solvent is refluxed at 160 to 200° C., high-purity monodisperse ruthenium dioxide can be produced without mixing of other materials. In the case of using a polar organic solvent, preferably ethylene glycol or diethylene glycol, a high temperature reaction of 160° C. or more can be performed, and as a result, monodisperse particles having a uniform size and no agglomeration can be prepared.

The reflux time for producing monodisperse particles may be 4 to 24 hours. If the reflux time is less than 4 hours, the monodisperse RuO ₂ particles are not well formed, and if the reflux time exceeds 24 hours, the particles become coarse and the usefulness decreases. In the present invention, the size of monodisperse RuO ₂ particles can be controlled by adjusting the reflux time. That is, when the reflux time is shortened, monodisperse particles having a small size can be produced, and when the reflux time is prolonged, monodisperse particles having a large size can be produced. Although the present invention is not limited thereto, monodisperse particles of 500 nm or less may be produced when the reflux time is less than 10 hours, and monodisperse particles of more than 500 nm may be produced when the reflux time is 10 hours or more.

The monodisperse RuO ₂ particles prepared by the method of the present invention are a group of RuO ₂ particles, and have advantages in that the size of the particles is relatively uniform, the particle groups form a sphere, and the boundaries of each group are clear. The monodisperse RuO ₂ particles of the present invention are advantageous in that they have a submicron size and do not cause aggregation between particle populations. The size of the monodisperse RuO ₂ particles of the present invention may be preferably 200-850 nm, more preferably 300-800 nm. When the monodisperse RuO ₂ particles have the same size as described above, they can be effectively used for supercapacitors and the like.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

[Example 1] Monodisperse RuO ₂ particle manufacturing

4.82 mmol (1.00 g) of RuCl ₃ nH ₂ O was sufficiently dissolved in 72 mL of ethylene glycol. After adding 0.4 mL of hydrogen peroxide (H ₂ O ₂ ) as an oxidizing agent, the mixture was stirred at room temperature for 30 minutes. After that, 0.5 g of polyvinyl pyrrolidone was added and stirred at room temperature for 30 minutes. Thereafter, 0.84 g of potassium hydroxide (KOH) was dissolved in 24 mL of ethylene glycol, put into the ruthenium solution, and stirred for 1 hour. Finally, spherical monodisperse RuO ₂ particles having a size of 700 to 850 nm were obtained through a reflux reaction at 180 °C for 12 hours. In order to remove remaining impurities, it is washed with secondary distilled water and ethanol. The monodisperse RuO ₂ particles prepared in the present invention do not have aggregation between particles and have clear boundaries between particles.

[Example 2] RuO using water as a solvent ₂ Preparation of Particles

After dissolving 4mmol (0.83g) of RuCl ₃ nH ₂ O in 30mL of distilled water in an autoclave reaction vessel, 1mL of hydrogen peroxide (H ₂ O ₂ ) as an oxidizing agent was slowly added drop-wise. . Thereafter, 3.0 g of sodium hydroxide (NaOH) was dissolved in 10 mL of distilled water, put into the ruthenium solution, and stirred for 4 hours. Finally, spherical ruthenium dioxide (RuO ₂ ) particles having a submicron size were obtained through hydrothermal synthesis at 180° C. for 12 hours. In order to remove residual impurities, it was washed several times with secondary distilled water.

[Example 3] Multifunctional RuO ₂ @Ag particle fabrication

1.00 g of ruthenium dioxide (RuO ₂ ) prepared in Example 2 is sufficiently dispersed in 50 mL of secondary deionized water. In another beaker, 0.10 g of silver precursor (AgNO ₃ ) is dissolved in 30 mL of secondary deionized water, 5 mL of 1M ammonium hydroxide (NH ₄ OH) aqueous solution is added, and the solution is dispersed through ultrasonic waves for 7 minutes. After that, a solution of silver precursor and ammonium hydroxide was added to the solution in which ruthenium oxide was dispersed, and then stirred in an ice bath for 45 minutes. In addition, a solution obtained by dissolving 0.15 g of polyvinyl pyrrolidone in 50 mL of ethanol was added to the solution being stirred, followed by stirring for 30 minutes. Finally, a reflux reaction was performed at 70 °C for 4 hours to obtain Ag nanoparticles attached to the surface of RuO ₂ . It is washed several times with secondary distilled water to remove residual impurities.

[Example 4] RuO ₂ Heat treatment of @Ag grains

The RuO ₂ @Ag particles prepared in Example 3 were heat-treated at 300° C. for 2 hours, and FE-SEM images and XRD images were measured.

1 (a) and (b) show FE-SEM images of monodisperse RuO ₂ particles synthesized in Example 1. In the case of FIG. 1 (a), monodisperse spherical particles with clear boundaries without agglomeration between particles can be confirmed. In the case of FIG. 1 (b), when the surface of the monodisperse RuO ₂ particles is confirmed at high magnification, it can be confirmed that the surface is rough. From these results, it can be confirmed that small RuO ₂ particles of several tens of nanometers were aggregated and synthesized into spherical monodisperse RuO ₂ particles of several hundred nanometers.

2 (a) and (b) are monodisperse ruthenium dioxide particles prepared according to Example 2, and have a diameter distribution of 300 nm to 800 nm, and in this case, it can be seen that the surface is smooth compared to the monodisperse ruthenium dioxide of Example 1. can

FIG. 3 shows the results of (a) submicron-sized RuO ₂ particles of Example 2, multifunctional RuO ₂ @Ag particles (b) obtained by attaching Ag particles to the sub-micron-sized RuO ₂ particles of Example 3, and (b) This is an FE-SEM image of multifunctional RuO ₂ @Ag particles (c) subjected to heat treatment at 300 °C for 2 hours. In the case of FIG. 3 (a), the RuO ₂ particles have a spherical shape with a size distribution of 300 nm to 800 nm, and the particle surface is relatively smooth. The RuO ₂ @Ag particles in FIG. 3 (b) have a spherical shape with a size distribution of 300 nm to 800 nm, as shown in FIG. 3 (a), and Ag particles of 50 to 70 nm are attached to the surface. The aggregation of Ag particles attached to the surface was not confirmed, and it could be confirmed as a single Ag particle. In the case of FIG. 3 (c), RuO ₂ @Ag particles subjected to a heat treatment process at 300 ° C. for 2 hours are shown. Compared to FIG. 3 (b), it can be seen that the Ag particles are well attached to the surface of the RuO ₂ particles without any change in appearance after the heat treatment process.

4 is a graph of submicron-sized RuO ₂ particles of Example 1 (black) and RuO ₂ @Ag particles (red) obtained by attaching Ag particles to sub-micron-sized RuO ₂ particles of Example 3 and Example 4 at 300 ° C. It shows an XRD pattern of multifunctional RuO ₂ @Ag particles (blue) subjected to a 2-hour heat treatment process. In the case of the RuO ₂ particles used in the synthesis, it was confirmed that the crystallinity was low, as diffraction occurred weakly at 2θ = 36 ° corresponding to the rutile structure. The RuO ₂ @Ag particles showed the Miller indices (111), (200), (220), and (311) of the standard Ag powder diffraction data (JCPDS card, # 04-0783), and the relative peak positions were consistent. It can be seen that the polycrystalline Ag particles are well attached to the RuO ₂ surface. In addition, in the case of RuO ₂ @Ag particles that have undergone the heat treatment process, the Miller indices (110), (101), (200), ₍ 211), (220), (002), (310), (112), (301), and (202) were shown, and the positions of the peaks were relatively consistent. After heat treatment, the crystallinity of RuO ₂ in RuO ₂ @Ag particles increased, resulting It can be confirmed that it has a (rutile) structure. From the results of FIGS. 3(c) and 4, it can be seen that Ag particles are well attached to the surface of RuO ₂ even after heat treatment. As a result, it can be confirmed that the Ag peak of the RuO ₂ @Ag particle is covered by a peak corresponding to a strong rutile structure.

Claims (11)

(1) dispersing monodisperse RuO ₂ in deionized water in container 1;
(2) dissolving a silver (Ag) precursor in deionized water in container 2, adding a reducing agent and stirring;
(3) preparing an alcohol solution of a surfactant in container 3;
(4) adding the solution in container 2 and the solution in container 3 to the solution in container 1 and stirring in an ice bath, and
(5) Method for producing a ruthenium dioxide-silver (RuO ₂ @Ag) complex comprising the step of refluxing the solution of step (4) The ruthenium dioxide-silver according to claim 1, characterized in that step (4) consists of adding the solution in container 1 to the solution in container 2 and stirring in an ice bath, then adding the solution in container 3 and stirring in an ice bath. (RuO ₂ @Ag) composite manufacturing method The method according to claim 1, wherein step (1) is a step of dispersing 30-100mL of deionized water per 1g of monodisperse RuO ₂ particles, and ruthenium dioxide-silver (RuO ₂ ) characterized in that ultrasonic waves are used to facilitate the dispersion. @Ag) Complex manufacturing method The method of claim 1, wherein the reducing agent is selected from the group _consisting of NH ₄ OH, NaBH ₄ , LiBH ₄ , LiAlH ₄ and ascorbic acid. The method according to claim 1, wherein step (5) is a step of refluxing at 60-90 ° C for _1-10 hours. The method according to claim 1, wherein the monodisperse RuO ₂
(a) dissolving a ruthenium precursor in water or a polar organic solvent, adding an oxidizing agent and an alkaline compound and stirring; and
(b) a method for preparing a ruthenium dioxide-silver (RuO ₂ @Ag) composite comprising the step of refluxing the solution The method according to claim 6, wherein the step (a)
(a-1) dissolving the ruthenium precursor in water and adding an oxidizing agent, and
(a-2) Process for preparing a ruthenium dioxide-silver (RuO ₂ @Ag) composite comprising the step of adding an alkaline compound to the solution of step (a-1) and stirring it The method according to claim 6, wherein the step (a)
(a-3) dissolving a ruthenium precursor in a polar organic solvent, adding an oxidizing agent and stirring;
(a-4) adding a surfactant to the solution of step (a-3) and stirring; and
(a-5) Adding an alkaline compound dissolved in a polar organic solvent to the solution of step (a-4) and stirring the ruthenium dioxide-silver (RuO ₂ @Ag) composite manufacturing method The method for preparing a ruthenium-silver (RuO ₂ @Ag) composite according to claim 6, wherein the oxidizing agent is hydrogen peroxide The method for preparing a ruthenium-silver (RuO ₂ @Ag) composite according to claim 6, wherein the alkaline compound is NaOH or KOH The method according to claim 6, wherein step (b) _is refluxed at 70 to 200 ° C for 4 to 24 hours.

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