KR20200062708A - Method for control the fractal dimension of graphene-based materials - Google Patents

Abstract

The present invention relates to a method for adjusting the fractal dimension of a graphene-based material. More particularly, the present invention is to provide a technique for developing various materials by adjusting the fractal dimension in a more convenient manner. According to various embodiments of the present invention, a reforming method for adjusting the porosity of the graphene-based material exhibits a remarkable effect on easily changing the fractal dimension of the graphene-based material. In addition, by adding an additive to the graphene-based material, it is possible to provide a material capable of being applied to various applications.

Description

Method for control the fractal dimension of graphene-based materials

The present invention relates to a method for adjusting the fractal dimension of a graphene-based material, and more particularly, to provide a technique capable of developing various materials by adjusting the fractal dimension in a simpler way than in the prior art.

The supercapacitor currently commercialized has a very low energy density compared to a secondary battery. In order to solve this problem, research on the development of new electrode materials using carbon materials such as graphene and carbon nanotubes has been actively conducted.

In general, graphene-based materials are considered very important technically because they have several excellent properties. In particular, graphene exhibits better electrical conductivity than any other conventional material, has greater thermal conductivity than diamond, and has a physical strength that is more than 200 times greater than steel at a weight of one-sixth. In addition, graphene has transparency, electrical properties, gas/moisture barrier properties, as well as flexibility and mechanical strength required in flexible devices. Since it can also be provided, it can be usefully used in an organic light emitting diode (OLED) display or a flexible display device that has recently been spotlighted. The graphene represents a carbon structure in the form of a nanosheet having a two-dimensional structure, and although it has excellent physical properties, technology development is limited. Accordingly, there is a need to develop a technique for synthesizing a three-dimensional graphene in order to improve the shortcomings of the two-dimensional graphene-based material.

However, since it is difficult to synthesize a 3D structured graphene-based material, mass production is impossible and it is difficult to control the fractal dimension. In addition, in the existing method, since it is made using an additive such as a metal oxide, it is difficult to manufacture a pure material, and has a problem in that it is difficult to control size, conductivity and shape.

Korean Patent Publication No. 2015-0080373

An object of the present invention is to provide a method for controlling the fractal dimension by adjusting the porosity of a graphene-based material rather than a conventional complex method.

In addition, mass production is possible in the form of an aqueous solution, and various properties can be controlled by adjusting the size and composition ratio of graphene-based materials. When additives are added, it is intended to provide a material that can be applied to various applications. .

According to an exemplary aspect of the present invention, a method for controlling a fractal dimension of a graphene-based material is characterized by controlling a porosity of the graphene-based material to adjust a fractal dimension.

The method of adjusting the fractal dimension of the graphene-based material

(A) modifying the graphene-based material; And

(B) forming the three-dimensional structure of the modified graphene-based material in an aerosol manner; it is preferable to include.

The step (A) is preferably hydrothermal treatment for 1 to 5 hours at a temperature of 40 to 60 ℃.

In step (B), it is preferable to form a three-dimensional structure by additionally adding an additive to the modified graphene-based material.

The additives are preferably metal-organic frameworks (MOFs) or metal particles comprising metal oxides.

The graphene-based material is preferably at least one selected from graphene oxide, reduced graphene oxide and graphene.

According to another exemplary aspect of the present invention, it relates to an electrode material including a graphene-based material having a fractal dimension adjusted through the fractal dimension adjustment method.

According to another exemplary aspect of the present invention, it relates to a battery including the electrode material.

According to various embodiments of the present invention, the modification method of controlling the porosity of the graphene-based material easily exhibits a remarkable effect in changing the fractal dimension of the graphene-based material.

In addition, by adding an additive to the graphene-based material, it is possible to provide a material that can be applied to various application fields.

1 is an image showing a graphene oxide solution (GO) and a modified graphene oxide solution (GO-1) used in Example 1.
FIG. 2 is a scanning electron microscope (SEM) image showing the results of analyzing the graphene oxide (GO) and the modified graphene oxide (GO-1) used in Example 1 with a scanning electron microscope.
3 is a TEM (Transmission Electron Microscope) image showing the results of analyzing the graphene oxide (GO) and the modified graphene oxide (GO-1) used in Example 1 with a transmission electron microscope.
4 is a SEM image showing the results of the analysis of the three-dimensional structure of graphene oxide and modified graphene oxide of Example 1 with a scanning electron microscope.
5 is a TEM image showing the results of analyzing the modified graphene oxide of the three-dimensional structure of Example 1 with a transmission electron microscope.
6 is a graph showing the results of BET (Brunauer-Emmett-Teller equation) analysis of graphene oxide and modified graphene oxide used in Example 1.
7 is a SEM image showing the results of analyzing the modified graphene oxide of the three-dimensional structure containing the additive of Example 2 with a scanning electron microscope.
8 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 1 hour at different magnifications through SEM.
9 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 3 hours at different magnifications through SEM.
10 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 5 hours at different magnifications through SEM.
11 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 5 hours at high magnification (b) and low magnification (a) and (c) through TEM.
FIG. 12 is an image of three-dimensional structures of graphene oxide modified by hydrothermal treatment of porous graphene oxide at different magnifications through SEM.
13 (a) and (b) are SEM images of a three-dimensional structure formed by hydrothermal treatment of modified porous oxide graphene, and (c) and (d) are three-dimensional structures of the existing graphene oxide subjected to hydrothermal treatment. It shows the SEM image created and observed.
14 (a) is a graph showing the results of a TGA (Thermogravimetry Analyzer) analysis of the porous graphene oxide modified by the reaction for 5 hours, and (b) is a SEM image.
15 is a graph showing the results of the N2 BET test of the porous graphene oxide modified by the reaction for 5 hours, and the fractal structure can be calculated through the slope of the graph.
16 is a SEM image of a three-dimensional structure made by mixing modified porous graphene oxide and ZIF-8, a type of MOF.
FIG. 17 is an image obtained by observing a three-dimensional structure made of a mixture of modified porous graphene oxide and ZIF-8, a type of MOF, at various magnifications through SEM.
FIG. 18 is a SEM image of a three-dimensional structure prepared by mixing modified porous graphene oxide and ZIF-8, a type of MOF, in powder form (top) and coating on a silicon wafer by dispersing it in methanol (bottom).

Hereinafter, various aspects and various embodiments of the present invention will be described in more detail.

According to an aspect of the present invention, there is provided a method for controlling a fractal dimension of a graphene-based material, which is characterized by controlling the porosity of the graphene-based material.

The method of adjusting the fractal dimension of the graphene-based material

(A) modifying the graphene-based material; And

(B) forming the three-dimensional structure of the modified graphene-based material in an aerosol manner; it is preferable to include.

More specifically, the step (A) is a step of modifying the graphene-based material and controlling the porosity formed on the surface of the graphene-based material.

The graphene-based material is more preferably modified in an aqueous solution state, because it is possible to control only the porosity formed on the surface without changing the size of the graphene-based material. In addition, as mass production is possible and the composition ratio of the graphene-based material can be easily adjusted, various physical properties may be controlled.

Specifically, it is preferable to hydrothermally treat the graphene-based material in the aqueous solution state at a temperature of 40 to 60° C. for 1 to 5 hours, when the temperature and time range are exceeded, the pore size is increased and oxidation occurs. It is not preferable because a problem that cannot maintain the shape and size of graphene occurs. More preferably, it is performed at a temperature of 50° C. for 1 to 5 hours.

As the graphene-based material, one or more selected from graphene oxide, reduced graphene oxide, and graphene may be used.

The step (B) is a step of forming a three-dimensional structure of the modified graphene-based material in an aerosol manner.

At this time, in addition to the graphene-based material, an additive may be additionally added to form a three-dimensional structure, and it shows an effect that can be applied to various materials depending on the type of the additive.

Specifically, the aerosol process is preferably performed at a temperature of 90 to 100 ℃, when outside the temperature range, the structural deformation due to the difference in the solvent content inside the three-dimensional graphene oxide or the degree of reduction of graphene oxide It is not preferable because problems may occur. The aerosol process time is not limited as it may vary depending on the size of the chamber containing the solution.

The additives are preferably metal-organic frameworks (MOFs) or metal particles comprising metal oxides. The metal-organic skeletal structure is characterized in that metal ions or clusters are coordinated with organic ligands such as ZIF (Zeolitic imidazolate frameworks)-8 to form 1, 2 or 3 dimensional structures. Preferably, the metal ion is at least one selected from Pt, Au, Ag, Si, Ti, Sn, Zn, Mg, Ni, Mn, Zr, B, Al, Fe, Cu, W, V, Co and Ba It contains a metal element, or one or more metal oxides selected from Fe ₃ O ₄ , MnO ₂ and SnO ₂ .

The metal particles include at least one metal element selected from Pt, Au, Ag, Si, Ti, Sn, Zn, Mg, Ni, Mn, Zr, B, Al, Fe, Cu, W, V, Co and Ba Or, it is more preferable to include at least one metal oxide selected from Fe ₃ O ₄ , MnO ₂ and SnO ₂ .

Hereinafter, the present invention will be described in more detail through examples and the like, but the scope and content of the present invention may be reduced or limited by the following examples and the like and cannot be interpreted. In addition, if it is based on the disclosure of the present invention including the following examples, it is obvious that a person skilled in the art can easily carry out the present invention in which experimental results are not specifically presented, and patents to which such modifications and corrections are attached Naturally, it is within the scope of the claims.

In addition, the experimental results presented below are only representative of experimental results of the examples and comparative examples, and the effects of various embodiments of the present invention, which are not explicitly presented below, will be described in detail in the corresponding parts.

Example 1 to 3: oxidation Graphene Through porosity control Fractal Dimension adjustment

To make pores in graphene oxide, add 5 mL of hydrogen peroxide and 5 mL of ammonia water to 100 mL of graphene oxide solution (concentration: 1 mg/mL) dispersed in water, and react at 50°C for 1 hour, 3 hours, and 5 hours, respectively. .(The longer the reaction time, the larger the porosity and the larger the porosity.) After the reaction is over, the centrifuge is separated for 90 minutes at 8000 rpm to separate the precipitate and the supernatant. After adding 50 mL of water to the precipitate and shaking it to disperse, put it in a dialysis tube and soak it in a beaker with water to remove the remaining chemicals. Change the water in the beaker 4 times a day for 3 days. The concentration of the solution from which impurities have been removed is calculated using a freeze-drying method and dispersed in water at a concentration of 1 mg/mL to be used as a solution. In order to create a three-dimensional structure, a particle generator was used, and an a-pipe was connected to the connecting portion where the particles are ejected to adjust the temperature to 90~100 ℃ using a heating tape. The a-pipe end is connected by a glass filter loaded with a polymer membrane capable of collecting particles, and the glass filter is connected with a vacuum pump. On the opposite side of the particle injection, nitrogen is blown in order to allow the particles to flow smoothly toward the glass filter. The reaction time may vary depending on the size of the particle generator chamber containing the solution. The fractal dimension of the sample reacted for 1 hour, 3 hours, and 5 hours was adjusted by the difference in porosity under the same experimental conditions.

Example 4: Three-dimensional structure containing additives Modified Oxidation Graphene Produce

After modifying graphene oxide in the same manner as in Example 1, after adding 0.2 wt.% of additive ZIF-8 compared to graphene oxide to increase the specific surface area (ZPGO), the same process conditions as in Example 1 were obtained. Graphene oxide having a three-dimensional structure was prepared.

1 is an image showing a graphene oxide solution (GO) and a modified graphene oxide solution (GO-1) used in Example 1.

Figure 2 is a SEM image showing the results of analyzing the graphene oxide (GO) and the modified graphene oxide (GO-1) used in Example 1 with a scanning electron microscope.

Referring to Figure 2, it can be seen that the shape and size of the modified graphene oxide is the same as the graphene oxide before modification.

3 is a TEM image showing the results of analyzing the graphene oxide (GO) and the modified graphene oxide (GO-1) used in Example 1 with a transmission electron microscope.

Referring to FIG. 3, it can be confirmed that pores were formed on the surface of the modified graphene oxide.

4 is a SEM image showing the results of the analysis of the three-dimensional structure of graphene oxide and modified graphene oxide of Example 1 with a scanning electron microscope.

5 is a TEM image showing the results of analyzing the graphene oxide of the three-dimensional structure of Example 1 with a transmission electron microscope.

6 is a graph showing the result that the specific surface area of the modified graphene oxide was improved through the BET (Brunauer-Emmett-Teller equation) results of the graphene oxide and the modified graphene oxide used in Example 1.

7 is a SEM image showing the results of analyzing the modified graphene oxide of a three-dimensional guzol containing the additive of Example 2 with a scanning electron microscope.

8 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 1 hour at different magnifications through SEM.

9 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 3 hours at different magnifications through SEM.

10 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 5 hours at different magnifications through SEM.

11 is an image obtained by observing the three-dimensional structure of the porous graphene oxide modified by the reaction for 5 hours at high magnification (b) and low magnification (a) and (c) through TEM.

FIG. 12 is an image of three-dimensional structures of graphene oxide modified by hydrothermal treatment of porous graphene oxide at different magnifications through SEM.

13 (a) and (b) are SEM images of a three-dimensional structure formed by hydrothermal treatment of modified porous oxide graphene, and (c) and (d) are three-dimensional structures of the existing graphene oxide subjected to hydrothermal treatment. It shows the SEM image created and observed.

14 (a) is a graph showing the TGA analysis results of the porous graphene oxide modified by the reaction for 5 hours, and (b) is a SEM image.

15 is a graph showing the results of the N2 BET test of the porous graphene oxide modified by the reaction for 5 hours, and the fractal structure can be calculated through the slope of the graph.

16 is a SEM image of a three-dimensional structure made by mixing modified porous graphene oxide with ZIF-8, a type of MOF.

17 is an image obtained by observing a three-dimensional structure made by mixing modified porous graphene oxide and ZIF-8, a type of MOF, at various magnifications through SEM.

FIG. 18 is a SEM image of a three-dimensional structure prepared by mixing modified porous graphene oxide and ZIF-8, a type of MOF, in powder form (top) and coated on a silicon wafer by dispersing in methanol (top).

Therefore, according to various embodiments of the present invention, it has a remarkable effect on easily changing the fractal dimension of the graphene-based material as a modification method for controlling the porosity of the graphene-based material.

In addition, by adding an additive to the graphene-based material, it is possible to provide a material that can be applied to various application fields.

Claims (8)

A method for controlling a fractal dimension of a graphene-based material, characterized by controlling the porosity of the graphene-based material to adjust the fractal dimension.
According to claim 1,
The method of adjusting the fractal dimension of the graphene-based material
(A) modifying the graphene-based material; And
(B) forming a three-dimensional structure of the modified graphene-based material in an aerosol manner; Fractal dimensional control method of the graphene-based material comprising a.
According to claim 2,
The step (A) is a method of controlling a fractal dimension of a graphene-based material, characterized in that hydrothermal treatment is performed at a temperature of 40 to 60°C for 1 to 5 hours.
According to claim 2,
The step (B) is a method for controlling a fractal dimension of a graphene-based material, characterized in that an additive is additionally added to the modified graphene-based material to form a three-dimensional structure.
According to claim 3,
The additive is a metal-organic skeletal structure or a method for controlling a fractal dimension of a graphene-based material, characterized in that the metal particles containing a metal oxide.
According to claim 1,
The graphene-based material is a method for controlling a fractal dimension of a graphene-based material, characterized in that at least one selected from graphene oxide, reduced graphene oxide and graphene.
Electrode material comprising a graphene-based material having a fractal dimension adjusted according to any one of claims 1 to 6.
A battery comprising the electrode material according to claim 7.

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