KR101013604B1 - fabrication method of electron emission source source - Google Patents

Abstract

It relates to an electron emission source and an electronic device to which the same is applied.

The electron emission source includes a conductive fixed film and a needle-like electron emission material layer which is physically directly fixed to the fixed film. The electrode may include a pinned layer and the acicular electron emission material layer may include a CNT layer. The needle-like electron-emitting material layer is formed using a suspension filtering method, and the electron-emitting material is fixed to each other by a fixed membrane by deposition.

Description

Fabrication method of electron emission source source

An embodiment of the present invention relates to an electron emission source and an electronic device using the same. Specifically, a cathode using a needle-shaped electron emission material, and It relates to an electron emission source and an electronic device to be applied.

In electron emission sources by microstructures, carbon nanotubes (CNTs) or nanoparticles and the like are preferred as electron emission materials. CNTs are known in various forms as microstructures grown or composited in the form of tubes or rods. Such CNTs have very excellent electrical, mechanical, chemical, and thermal properties, and have been applied to various fields due to these advantages. CNTs have a low work function, high aspect ratio, very large field enhancement factor because the top end or emission end has a small radius of curvature, Therefore, electrons can be easily emitted even under a low potential electric field.

Known methods for producing CNT electron emitters include CNTs grown vertically directly on a conductor, such as a cathode or substrate, or CNT powder synthesized in a separate process to a conductor.

As a method of growing CNTs, many direct growth methods are known in which CNTs are grown on a fine catalyst metal using a hydrocarbon gas decomposed at high temperature. (Reference: Science vol. 283, 512, 1999; Chemical Physics Letters. 312, 461, 1999; Chemical Physics Letters. 326, 175, 2000; Nano Letter vol. 5, 2153, 2005; US006350488B1; US006514113B1)

Methods for attaching the pre-synthesized CNT powder on the cathode substrate include suspension filtering method, screen printing method, electrophoresis method, self assembling method, spray method, inkjet printing method and the like.

Suspension filtration filters the CNT suspension into a filter having micropores to transfer the CNTs remaining in the filter to a Teflon coated cathode substrate. (Reference: Science vol. 268, 845, 1995; Applied Physics Letters vol. 73, 918, 1998),

Screen printing method forms a CNT thin film by printing and baking a paste mixed with a vehicle, an inorganic binder and other additives containing a polymer and an organic solvent, and a CNT powder on a cathode substrate. (Reference: Applied Physics Letters vol. 75, 3129, 1999; Patent Publication No. 10-2007-0011808)

Electrophoresis method attaches a CNT to a cathode substrate by electrophoresis while the cathode substrate is immersed in an electrolyte solution in which the CNT powder is dispersed in a surfactant. (Ref .: Advanced Materials vol. 13, 1770, 2001; Nano Letter vol 6, 1569, 2006; US006616497B1; US20060055303A1).

The self-assembly method involves vertically placing a hydrophilic substrate in a well-dispersed suspension of hydrophilic surface-modified CNTs in a deionized water solution and forming a CNT thin film by gradual vaporization of the solution (Ref .: Advanced Materials vol. 14, 8990, 2002; US006969690B2)

The spray method sprays a well dispersed CNT suspension through a spray nozzle to form a thin film of CNT on the cathode substrate. (Ref. Mat. Res. Soc. Symp. Proc. Vol. 593, 215, 2000; Carbon vol. 44 , 2689, 2006; The Journal of Physical Chemistry C. 111, 4175, 2007; US006277318B1; Pub. 10-2007-0001769).

The inkjet printing method prints a well-dispersed CNT suspension on a cathode substrate with an inkjet printer to form a CNT thin film. (Ref. Small. Vol. 2, 1021, 2006; Carbon vol. 45, 27129, 2007; US20050202578A1 )

 In the above known methods, the direct growth method deposits a nano-sized catalytic metal by sputtering, thermal evaporation, or electron beam evaporation on a conductive or non-conductive cathode substrate, and then vapor and liquid carbonation sources by chemical vapor deposition. A method of producing vertically aligned CNT field electron emission sources by pyrolysing gas at high temperature. The method is easy to control the structure of the diameter, length, density, patterning, etc. of the CNT, but it is not only difficult to secure the overall homogeneity and control the size of the catalyst metal particles when depositing the catalyst metal to a large area (large area) Therefore, the adhesion between the grown CNT and the cathode substrate is weak and not easy to large area.

In order to solve the problem of adhesion between CNT and cathode substrate and difficulty of large area of CNT field electron emission source, CNT powder prepared by various synthetic methods is purified, dispersed and functionalized to paste or solvent and surfactant. Various methods have been developed for attaching a suspension dispersed in a cathode substrate. Among them, CNT paste composition containing CNT powder, polymer, binder, polymer, organic solvent, metal filler, and other additives is printed on the cathode substrate, followed by drying, exposure, firing, and surface protruding process to produce CNT electron emission source. The screen printing method to fabricate the film has good adhesion between the cathode substrate and the CNT electron emission source and is advantageous for large area, but it is difficult to control the density of the active electron emission site, and electric field emission is caused by various organic or inorganic binders and polymers. Not only are the properties easily degraded, but the process procedures are difficult. In the electrophoresis method, CNT powder and anodic dispersant are mixed with an electrolyte to make a well dispersed CNT suspension, and then, two electrode substrates are put in the CNT suspension, an electric field is applied, and a negatively charged CNT is charged in the electric field. As a method of fabricating a CNT field electron emission source by depositing on the applied cathode substrate, selective deposition is possible at room temperature and is easy to large area, but it is difficult to control thickness and density, poor homogeneity and reproducibility, and adhesion to cathode substrate. As a result, reliability and stability problems have arisen in the field emission.

On the other hand, the self-assembly method of vertically placing a hydrophilic substrate in a suspension in which hydrophilic surface-modified CNTs are dispersed in deionized water and then forming a CNT field electron emission source by gradual vaporization of a solution is simple and large area at room temperature. Although it is easy to paint, it has a disadvantage that the adhesion between the formed CNT thin film and the cathode substrate is not good and takes a lot of time as in the electrophoresis method.

Similarly, the spray method is simple and easy to obtain a large area at room temperature.However, the surface state of the thin film is determined by the degree of suspension evaporation during the movement of the spray liquid from the nozzle to the cathode substrate. Since it is not easy to be homogeneous and reproducible, there is a problem that the CNT easily falls off during the field electron emission period due to the weak adhesion with the cathode substrate.

In the method of manufacturing an electron emission source using an ink jet printer, a suspension made by dispersing hydrophilic surface-modified CNT powder in deionized water is selectively printed on a cathode substrate to form a CNT field electron emission source. This method is easy to control the thickness and density of the CNT film, can realize selective patterning and is advantageous for large area at room temperature, but the weak adhesion between the printed CNT field electron emission source and the cathode substrate is a problem. In addition, a suspension filtering method in which a well-dispersed CNT suspension is filtered onto a filter paper having micropores and simply transferred onto a Teflon-coated metal substrate to form a CNT field electron emission source, adjusts the amount or concentration of CNT powder to control thin film thickness and density. Although it is easy to adjust and the process is simple, it is advantageous to make a large area. However, the adhesion between the CNT thin film and the cathode substrate has been a problem.

Unlike filtering CNT suspensions to form CNT thin films and then transferring them onto cathode substrates, US 2004/0166235 A1 uses CNT thin films vertically aligned by direct growth where conductive silver paste is patterned on metal substrates. CNT transferred to the adhesive sheet from the vertically aligned CNT thin film by direct growth method where it is bonded and thermally compressed and transferred, or where a patterned conductive layer is deposited on the glass sheet and a conductive carbon (silver, gold, etc.) paste is deposited on the conductive layer. A method of producing a CNT field electron emission source by transferring to them is disclosed. However, this method is difficult to large-area vertically aligned CNT thin films by direct growth method, so that drying, compression, heating, or thermal compression is performed so that a large area may be limited and adhesion may be well achieved when transferring. There is also a disadvantage of going through a complicated process.

In the manufacture of CNT electron emission sources, it is desirable to combine reliability, stability and economy. In order to manufacture high quality CNT electron emission sources, it is necessary to suppress the incorporation of impurities that adversely affect the electron emission. In addition, CNT density control should be easy for homogeneous and reproducible electron emission. In addition, in order to secure the reliability and stability of the CNT electron emission source, it is required to improve the adhesion between the CNT and the cathode supporting the same. In addition, in order to secure economics in manufacturing CNT electron emission sources, the manufacturing process procedure should be simple and large area should be easy.

According to an embodiment of the present invention, a method of manufacturing an electron emission source that is easy to manufacture, high in reliability, and has a high current density is provided.

According to an embodiment of the present invention, an electronic device and a method of manufacturing the same, which are easy to manufacture, have high reliability, and apply an electron emission source having a high current density, are provided.

According to one type of the invention,

An electron emission unit including a needle-shaped electron emission material; and

A fixing film in which one end of the needle-like electron-emitting material is fixed by supporting the electron-emitting part, a supporting layer supporting the fixed film from below, and a conductive adhesive layer between the fixed film and the supporting film Provided is an electron emission source comprising an electrode with an adhesive layer).

According to another embodiment, the adhesive layer may include a conductive particle that mediates the bonding between the pinned layer and the support layer. According to a specific embodiment, the conductive particle may include at least one of nickel, copper, silver, carbon, and aluminum. It can be formed as one.

According to another embodiment, the fixed membrane may have a loose texture having a void.

According to another specific embodiment, the electron-emitting material layer is at least one of single-walled (SW) CNT, double (walled) CNT, multi-walled (NTW) CNT, carbon nanofibers, semiconductor nanowires, conductive nanorods It may include any one.

According to another specific embodiment, the support layer may be formed of any one of aluminum, copper, nickel, the fixing layer may be formed of any one of titanium, chromium, silver, gold, and the conductive particles are nickel Can be formed.

According to another type of the invention,

Forming an electron emission unit including the acicular electron emission material in the template;

Depositing a conductive material layer on the electron emission unit to form a fixed layer which fixes the electron emission material to each other; And

Adhering the fixed film to the conductive support film by an adhesive, separating the template and the electron emitting part, and obtaining an electron emission source including an electron emitting part, a fixed film and a support film fixing the same. It is provided in the manufacturing method.

According to an embodiment of the present disclosure, the template may be a filter paper having a plurality of cavities, and the forming of the electron emitting portion may include applying and drying a suspension in which acicular electron emitting materials are dispersed.

According to another type of the invention,

Forming an electron emission unit including the acicular electron emission material in the template;

Depositing a conductive material layer on the electron emission unit to form a fixed layer which fixes the electron emission material to each other;

Transferring a fixed film formed on the template and an electron emitting part fixed thereto by a conductive support film having an adhesive layer formed on one surface thereof; And

A method of manufacturing an electron emission source is provided, comprising: heat-treating a fixed film to which the electron emission unit is fixed and a support film supporting the same.

According to other embodiments of the manufacturing method, the method may further include activating the surface of the electron-emitting material fixed to the fixed membrane. According to a specific embodiment, the activating may be performed by the surface of the electron-emitting material. It may include any one of a taping treatment for raising the electron-emitting material by a plasma treatment, a laser treatment or a tape having an adhesive force. In addition, the taping treatment causes the electron-emitting material to stand against the supporting part by pressing the surface of the electron-emitting part with an electing member having an adhesive force to the electron-emitting material.

According to another embodiment, the adhesive may be an adhesive including conductive particles. According to another embodiment, the conductive support layer may be provided by a conductive adhesive tape coated with an adhesive including the conductive particles on one surface. Can be.

According to another embodiment, the fixed membrane and the support membrane may be heat treated to bond the fixed membrane and the support membrane through the conductive particles.

The present invention prepares a well-dispersed CNT colloidal suspension of various kinds of needle-like electron-emitting material, that is, a tube or rod-shaped electron-emitting material having a certain length, for example, CNT powder using a suspension filtering method, and these are fine pores After supplying the suspension over a filtration template with filtration, it is filtered and dried to form a CNT layer with density optimized for field electron emission. The CNTs dispersed in the suspension are uniformly dispersed, and thus the CNT layer formed on the template also has a uniform distribution of CNTs. Then, a conductive material such as a metal is deposited on the CNT layer to form a fixed membrane having a function as an electrode and mutually fixing the CNTs, and then separating the CNT layer from the template to obtain a stable and firmly fixed CNT layer on the fixed membrane. Subsequently, the surface treatment of the subsequent CNT layer raises and vertically aligns the CNT with respect to the supporting film, thereby dramatically increasing the number of CNTs that contribute to the electron emission.

Therefore, the electron emission source according to the present invention is structurally very stable and can emit electrons of high and even distribution.

The present invention can produce an electron emission source as a single item separately from the overall manufacturing process of the electronic device applying the electron emission source. Therefore, it is possible to prevent contamination of electronic devices due to conductive organic / inorganic materials, binders, polymer pastes, etc., which may occur when the electron emission source is made together with the manufacture of the electronic device. In addition, since the electron emission source is manufactured separately, the manufacturing of the electronic device can be made without a complicated process, and in particular, the large area is easy. In particular, since it is easy to obtain a large electron emission area, it is possible to have one CNT layer in one pixel, for example, in a display device.

Hereinafter, an electron emission source, a display using the same, and a manufacturing method thereof according to exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 shows a schematic structure of a single electron emission source according to an embodiment of the present invention.

The present invention utilizes a needle-shaped electron emission material. Needle-shaped electron-emitting materials include hollow nanotubes, filled nanorods, and the like, and representative materials thereof are carbon, and other materials may be produced by metallic materials. In the following description of the embodiment will be described based on the carbon nanotube (CNT) which is a representative material of the acicular electron emission material. However, any material capable of electron emission as a needle may be applied, and thus the present invention is not limited by a specific example of the needle electron emission material.

Referring to FIG. 1, an electron emission source 10, commonly referred to as a cathode structure, includes a CNT layer 13 including a plurality of CNTs 13a and an electrode 12 supporting the bottom thereof. The electrode 12 is a fixed film 12a that physically fixes the lower end 13a 'of the CNT 13a, a support film 12b under the fixed film 12a, and a support film under the fixed film 12a. The conductive adhesive layer 12c between 12b is included. As shown in FIG. 1, the lower end portion 13a ′ of the CNT 13a is planted in the fixed membrane 12a. That is, the fixed membrane 12a physically firmly fixes the CNT 13a, and thus has a firm fixed structure of high strength compared to the fixed strength of the conventional CNT grown on the catalyst. The pinned film 12a is obtained by the deposition of a conductive material such as a metal including aluminum on the CNT layer 13, which will be described later in detail. In addition, a support layer 12b is formed under the fixed layer 12a. The support layer 12b is separately manufactured and then combined with the fixed layer 12a by a conductive adhesive layer 12c. The adhesive layer 12c may include an adhesive material and is conductive. The conductivity of the adhesive layer 12c is imparted by the conductive particles contained in the adhesive layer 12c.

Referring to FIG. 2, the electron emission source 10a according to the embodiment of the present invention includes an electrode 12 including the pinned layer 12a, the support layer 12b, and the adhesive layer 12c on the base 11. The CNT layer 13 as described above is formed on the electrode 12. The base 11 may have a function as part of an electrode for providing a current path together with the electrode 12 by being formed of a conductor, and when the base 11 is formed of a non-conductor, may be a lower support structure of the electron emission source 10. have. Here, the base 11 is represented symbolically, and may be designed in various forms according to the application field of the electron emission source according to the present invention, which obviously does not limit the technical scope of the present invention. Meanwhile, another functional layer may be interposed between the fixed membrane 12a and the base 11, which also does not limit the technical scope of the present invention.

Here, the conductive particles may be included in the adhesive when the base 11 has a function as some element of the electrode 12. The pinned film 12a and the support film 1b are formed of a conductive material such as a metal including aluminum as the components of the electrode 12. The pinned film 12a may have a thickness from several nm to several μm, which can be easily adjusted according to design conditions.

According to another embodiment, an adhesive conductive tape having an adhesive layer applied to at least one surface of the support film 12b may be used. Here, the adhesive layer on one side of the conductive tape corresponds to the adhesive layer between the fixed film 12a and the support film 12b. In addition, when an adhesive is present on both sides of the support film 12b, a conductive double-coated tape having an adhesive applied to both surfaces of the metallic tape may be used.

1 and 2, the pinned layer 12a and the lower support layer 12b are shown to have a flat surface. According to another embodiment, the pinned layer 12a and the lower support layer 12b may have an uneven surface. The pinned layer 12a may have a loose texture having a partial void. Therefore, the shape of the fixed membrane 12a or the support membrane 12b and the presence of voids do not limit the technical scope of the present invention. However, the rough shape may improve the aspect ratio of the CNT layer 13 to increase the field concentration effect, thereby making it easier to emit electrons from the CNT layer 13.

Such electron emission sources can be applied to electronic devices of various fields. For example, these electronic devices include a visible light source used for illumination, a backlight device for flat panel displays, an electron source for X-RAY devices, an electron source for high power microwaves, and the like. Such an electron emission source may be formed in a planar shape, but may have various forms such as non-planar, for example, curved curved or spherical shapes fixed to a three-dimensional structure. It does not limit the technical scope of the.

In the above structure, the fixed film 12a, or the electrode 12 including the fixed film 12a and the support film 12b, has an appropriately controlled electrical resistance as a conductor, thereby providing a fixed film ( A uniform current supply to the CNT layer 13 fixed to the surface of 12a) is possible throughout, thus enabling uniform electron emission throughout the CNT layer 13.

Hereinafter, an exemplary embodiment according to the method of manufacturing a single electron emission source of the present invention will be described.

First, a CNT colloidal suspension (hereinafter referred to as a suspension) and a filter paper (filtration template) made of materials such as Teflon, ceramic, Aanodic Aluminum oxide (AOA), and polycarbonate are prepared as templates. A suspension is a colloidal liquid made by dispersing powdered CNTs in a solvent and a surfactant. In this case, the surfactant is an optional material, and the liquid may not include the surfactant. It is desirable to sonicate for more even dispersion. The filter paper filters the suspension, leaving only CNTs on its surface, to dry the CNT suspension and to retain only the CNTs in a predetermined pattern for transfer to the plate cathode. CNTs include single-walled carbon nanotubes (SWCNTs), double-walled carbon nanotubes (DWCNTs), thin multi-walled carbon nanotubes (MWCNTs), and thick MWCNTs. The solvent is any one of ethanol, dimethyl formamide, tetrahydrofuran, dimethyl acetamide, 1,2 dichloroethane and 1,2 dichlorobenzene.

And the surfactant is sodium dodecylbenzene sulfonate (NaDDBS C1 ₂ H ₂₅ C ₆ H ₄ SO ₃ Na), sodium butylbenzene sulfonate (NaBBS C ₄ H ₉ C ₆ H ₄ SO ₃ Na), sodium benzoate (C ₆ H ₅ CO ₂ Na), sodium dodecyl sulfate (SDS; CH ₃ (CH ₂ ) ₁₁ OSO ₃ Na), Triton X-100 (TX100; C ₈ H ₁₇ C ₆ H ₄ (OCH ₂ CH ₂ ) n-OH; n 10), dodecyltrimethylammonium bromide (DTAB; CH ₃ (CH ₂ ) ₁₁ N (CH ₃ ) ₃ Br) or Arabic gum.

As shown in Fig. 3A, a filtration template 21 made of filter or the like is prepared.

As shown in FIG. 3B, the suspension is applied in a predetermined pattern and then dried to form a CNT film 13 '. The application area of the suspension depends on the form of the cathode (electron emitting portion) of the electron emission source, and various changes are possible depending on the type of cathode required for the application. Here, by controlling the ratio or concentration of the solvent, the surfactant and the CNT of the suspension, the CNT density can be freely adjusted and the optimal electron emission density can be realized according to the ambient electrical conditions, and the optimum conditions can be repeatedly reproduced and homogenized. Density CNT films can be formed. A suspension is formed in the filtration template 21, with only CNT remaining and the liquid material passing through the filtration template. When the drying process is performed in this state, the CNT film 13 ′ is formed on the surface of the template 21. This process may include a natural drying or vacuum drying process at room temperature or high temperature.

As shown in FIG. 3C, a conductive material, for example, aluminum is deposited on the CNT film 13 ′ to form a pinned film 12a that fixes the CNTs of the CNT film 13 ′ to each other.

As shown in FIG. 3D, the CNT membrane 13 ′ is separated from the filtration template 21, and a plurality of CNTs in which a fixed membrane 12a and a lower end 13b thereof are physically fixed to the fixed membrane 12a. An electron emission source 10 having a CNT layer 13 having a 13a is obtained. Here, the separation method may use the same transfer as in the method described below. According to another embodiment, the filtration template may be heat-treated with the fixed membrane 12a and the CNT membrane 13 by high temperature heat treatment. (21) has a method of removing by pyrolysis.

After the filtration template 21 is removed or separated as described above, a step for raising the CNTs with respect to the fixed membrane by surface treatment of the CNT membrane fixed to the fixed membrane 12a may be performed. This is explained in detail later.

The above process describes the embodiment of the most basic form, it is possible to apply in various forms. The following description relates to a method of manufacturing an electronic device including a method of transferring the electron emission source 10 to the support film 12b.

As shown in FIG. 4A, first, a supporting film 12b having adhesive layers 121 and 122 provided on one surface or both surfaces thereof is prepared. The support film 12b may be provided by a conductive adhesive tape provided with an adhesive layer on one or both surfaces. In FIG. 6A, the adhesive layer is formed on both surfaces, but according to another exemplary embodiment, the adhesive layer 121 may be provided only on one surface corresponding to the pinned layer 12a. In an embodiment in which adhesive layers are provided on both sides, the lower adhesive layer 122 will be protected by a release paper that prevents adhesion of foreign substances during the actual process, and is not shown in the drawings. As the conductive film 12b, a conductive fabric, a metal plate, or the like may be applied as the conductive material. The adhesive layers 121 and 122 may have conductivity, and may be formed of a material in which conductive particles, for example, modified nickel and a polymer resin are mixed. Specifically, the support layer 11 may be formed of aluminum foil (thickness: 0.01 to 0.04 mm), a conductive sheet (thickness: 0.01 to 0.04 mm) made of copper or nickel, and a conductive fabric (thickness). : 0.01 to 0.20 mm). That is, the cathode 11 may be formed of any one of a conductive sheet containing any one of aluminum, copper, and nickel and a conductive fabric.

The adhesive layers 121 and 122 are mixtures of conductive powders such as nickel and carbon pigments and adhesive resins such as acrylic ester polyol copolymers, and preferably have a total contact resistance of less than 0.1 Ω / 25 mm ² . And an allowable temperature range of -30 ° C to 105 ° C.

As shown in FIG. 4B, the support layer 12b is contacted with a predetermined pressure with respect to the fixed membrane 12a covering the CNT film 13 'on the template 21, and then separated from the template 21. CNT film 13 'is formed on the support film 12b side as a CNT film 13 for electron emission.

The process of FIG. 4C illustrates a method for surface treatment of a CNT layer in which the CNTs 13a of the CNT layer 13 are arranged in a disordered manner in a fixed layer 12a. As shown in (a) of FIG. 4C, the adhesive tape 22 is adhered to the CNT layer 13 on the support film 12b and then lifted off. In this way, the CNT exposed on the surface of the CNT layer 13 is aligned in a direction perpendicular to the supporting film 12b or the fixed film 12a by the adhesiveness of the tape 22. That is, the tape 22 is used to raise the electrode 12 including the fixed film 12a and the support film 12b. In addition to the method of using such a tape 22, as shown in (b) of FIG. 4C, the CNTs are formed by rolling the surface of the CNT layer 13 to a predetermined pressure by rolling a roller 23 having adhesiveness to the surface. Can be raised to align vertically. In this vertical alignment process, the CNTs weakly fixed to the fixed layer 12a of the electrode 12 will be separated therefrom and removed, but most of the CNTs have their lower ends fixed in a buried manner in the fixed layer 12a. It will be vertically aligned in a way that it sounds upwards.

After the transfer of the CNT layer 13 and the vertical alignment of the CNT 13a are completed through the above-described process, when the heat treatment is performed, all the organic components that may be included in the adhesive layers 121 and 122 on both sides of the support layer 12b are obtained. And if there are nano-sized conductive particles there, these conductive particles will be present as mediators for bonding the fixed film 12a and the support film 12b of the electrode 12, as shown in FIG. will be.

Referring to FIG. 5, through the heat treatment process, all organic components of the adhesive layer 121 are removed and conductive particles 121a remain therein, and the fixed film 12a thereon is roughly deformed and voids in the middle. (12a ') will have a sex muscle tissue. In this case, the conductive particles 121a serve as a medium for bonding the fixed film 12a and the support film 12b to each other, thus improving the contact characteristics between the fixed film 12a and the support film 12b. Emission performance will improve.

FIG. 6A is a planar SEM image of a sample subjected to heat treatment first and then surface treated with a tape or the like. FIG. This image shows the presence of nickel, the conductive particle of the adhesive layer, under the fixed membrane, the metal layer that holds the CNTs. 6B shows that the metal layer (fixed film) is covered on the nickel particles as an image obtained in the inclined direction. 6C is an enlarged view of a portion of FIG. 6B. As shown in FIG. 6C, the CNT is firmly fixed on the metal layer and shows that nickel particles are present under the metal layer, in particular, the CNT is physically bonded to the metal layer, that is, the fixed membrane. This condition was maintained even after five surface treatments. 6D shows an enlarged image of the CNT layer and the metal layer (fixed layer), showing that the lower end of the CNT is buried in the metal layer, that is, the fixed membrane, that is, it is physically fixed.

7 shows an electron emission source (Sample 1) having a fixed membrane to which CNTs are fixed and conductive particles are present between the fixed membrane and the support membrane, and an electron emission source to which CNTs are directly attached to the support membrane by an adhesive without the fixed membrane. This is a current (I) -voltage (V) graph (log scale) comparing the emission characteristics of 2). Here, Sample 1 is a state in which the organic component of the adhesive between the fixed membrane and the support membrane is removed by heat treatment, so that the conductive particles directly bond the fixed membrane and the support membrane, and Sample 2 is a CNT fixed to the support membrane by the adhesive. Organic components remain in the adhesive without heat treatment.

Referring to FIG. 7 showing IV characteristics of these two electron emission sources, the electron emission source of Sample 1 is a turn-on field, that is, an electric field required to reach a current density of 0.1 mA / cm ² . The (field) is 0.4 V / µm, which is about 0.5 V / µm lower than that of Sample 2 (0.9 V / µm). In addition, the threshold field, that is, the electric field required for the current density to reach 1 mA / cm ² , is 0.7 V / µm for the electron emission source of Sample 1, which is about 1.7 V / um for the electron emission source of Sample 2. As low as 1 V / um. As described above, the excellent current density of Sample 1 is understood to be due to the fixed film that is heat treated and has a rough surface by the conductive particles below it. That is, in the process of heat-treating the sample 1, the organic component of the adhesive layer positioned below the fixed membrane is removed, and the remaining conductive particles fix the fixed membrane and the support membrane to each other. At this time, the fixed membrane has a very rough shape, and eventually, the aspect ratio increases, thus accompanied by the field concentration effect.

8 is a FN graph comparing the emission characteristics of each of Sample 1 and Sample 2 as described above. In FIG. 8, β represents a field enhancement factor, which represents the effect of the shape (or structure, morphology) of the electron emission source on the emission, and the larger the value, the easier the field emission is. As can be seen in Figure 8, the electron emission source of the sample 1, the aspect ratio increased due to the rough shape, the value of the field enhancement factor increased about 5 times compared to the electron emission source of the above-described sample 2.

Thus far, exemplary embodiments have been described and illustrated in the accompanying drawings in order to facilitate understanding of the present invention. However, it should be understood that these embodiments are merely illustrative of the invention and do not limit it. It is to be understood that the invention is not limited to the details shown and described. This is because various other modifications may occur to those skilled in the art.

1 shows a schematic structure of an electron emission source according to an embodiment of the present invention.

2 shows a schematic structure of an electron emission source according to another embodiment of the present invention.

3 shows a schematic structure of an electron emission source according to another embodiment of the present invention.

4 shows a schematic structure of an electron emission source according to another embodiment of the present invention.

5A to 5D are flowcharts illustrating a method of manufacturing an electron emission source according to an embodiment of the present invention.

6A to 6C are flowcharts illustrating a method of manufacturing an electron emission source according to another exemplary embodiment of the present invention.

7 is a schematic cross-sectional view of an electron emission source manufactured according to an embodiment of the present invention.

8A to 8D are SEM images showing the actual structure of an electron emission source manufactured according to an embodiment of the present invention.

9 is a graph showing I-V characteristics of an electron emission source having no fixed film and an electron emission source according to another embodiment of the present invention.

FIG. 10 is a graph showing F-N characteristics of an electron emission source having no fixed film and an electron emission source according to another embodiment of the present invention.

Claims (28)

delete delete delete delete delete delete delete delete delete delete Forming an electron emission part including the acicular electron emission material on the template by using the acicular electron emission material on the powder; Depositing a conductive material layer on the electron-emitting part to form a fixed film to which end portions of the acicular electron-emitting material are planted and fixed; And Adhering the fixed film to the conductive support film by an adhesive, separating the template and the electron emitting part, and obtaining an electron emission source including an electron emitting part, a fixed film and a support film fixing the same. Manufacturing method. The method of claim 11, The template is a filter paper having a plurality of cavities, wherein the step of forming the electron emitting portion comprises the step of applying and drying a suspension of acicular electron-emitting material dispersed. 13. The method according to claim 11 or 12, And activating a surface of the acicular electron emission material fixed to the fixed membrane. The method of claim 13, The activating step may include any one of a treatment of plasma treatment of the surface of the acicular electron emitting material, a taping treatment of raising the acicular electron emitting material by a tape having adhesive force, and an taping treatment. Manufacturing method. The method of claim 14, The taping treatment is characterized in that the electron-emitting material is erected against the support by pressing the surface of the electron-emitting part with an electing member having an adhesive force to the acicular electron-emitting material and separating it. Manufacturing method. 13. The method according to claim 11 or 12, And said adhesive comprises a conductive particle. The method of claim 16, The conductive support film is a method for producing an electron emission source, characterized in that provided by a conductive adhesive tape coated with an adhesive containing the conductive particles on one surface. The method of claim 17, And heat treating the fixed film and the support film to bond the fixed film and the support film through the conductive particles. delete delete Forming an electron emission unit including the acicular electron emission material in the template; Depositing a conductive material layer on the electron-emitting part to form a fixed film to which end portions of the acicular electron-emitting material are planted and fixed; Transferring a fixed film formed on the template and an electron emitting part fixed by the conductive support film having an adhesive layer formed on one surface thereof; And And heat-treating the fixed membrane to which the electron-emitting unit is fixed and the support membrane supporting the fixed membrane. The method of claim 21, A conductive particle is included in the adhesive layer, and the fixed film and the support film are bonded to each other via conductive particles by the heat treatment. The method of claim 21 or 22, And activating a surface of the electron-emitting material fixed to the fixed membrane. The method of claim 23, The activating step And a taping treatment for raising the electron-emitting material by a tape having a plasma treatment, a laser treatment, or an adhesive tape on the surface of the needle-like electron-emitting material. The method of claim 24, The taping treatment is characterized in that the needle-emission material is erected against the support by pressing the surface of the electron-emitting part with an electing member having an adhesion to the needle-like electron-emitting material and then separating it. Original manufacturing method. delete delete delete

Images