JP4525595B2 - Manufacturing method of electron emission source - Google Patents

Description

  The present invention relates to an electron emission source and a manufacturing method thereof, and more particularly to a manufacturing method capable of easily forming an electron emission source that can be employed in a field emission display (hereinafter referred to as FED), an electron beam source, a micro vacuum tube, and the like. .

In recent years, many studies have been conducted on nanostructured carbon materials having a diameter on the order of nanometers (nm), such as carbon nanotubes, carbon nanofibers, and graphite nanofibers. Among these, the carbon nanotube has a structure in which a network graphene sheet in which carbon 6-membered rings are connected on a plane is wound in a cylindrical shape and connected so that there is no seam. One composed of a single graphene sheet is called a single-wall nanotube, and a plurality of graphene sheets laminated in a nested manner are called multi-wall nanotubes. Graphite nanofibers are a stack of columnar structures in which the graphene sheets have an ice cream cone shape with the tip cut off, and the shape of the graphene sheets that conform to the surface shape of the catalyst metal used for formation. It is a material having a different structure.
By the way, when an electric field with a certain threshold value or more is applied to a metal or semiconductor placed in a vacuum, electrons pass through the energy barrier near the surface of the metal or semiconductor by the quantum tunneling effect, and even in normal temperature in vacuum. Electrons are emitted. Electron emission based on this principle is called cold cathode field emission, or simply field emission. A field emission display (hereinafter referred to as FED) is a display that emits light by making electrons emitted using this principle collide with a phosphor. Nanostructured carbon materials are superior in performance such as electron emission characteristics, heat resistance, and chemical stability, so in recent years, they are expected to be used in electron emission sources that apply the above-mentioned field emission principle to image display. ing. Moreover, since it has the property of becoming a semiconductor and a conductor, it is also expected to be applied to electronic and electrical devices.
Conventionally, nanostructured carbon materials have been manufactured by arc discharge method, thermal CVD method, vacuum plasma method, etc. For example, in Patent Document 1, a substrate on which a catalytic metal thin film is formed is heat-treated under vacuum and then subjected to thermal CVD method. A graphite nanofiber thin film is selectively formed at a predetermined location on a substrate. Patent Document 2 discloses that a microwave output for generating plasma in a vacuum film forming chamber is temporally modulated on a substrate. It is described that carbon nanotubes are produced by being oriented in the vertical direction. In addition, in order to use the nanostructured carbon material for a substrate of an electron beam apparatus such as an FED, it is necessary to pattern a layer formed of the nanostructured carbon material. In addition, it is described that patterning is performed on a nanostructured carbon material using a photolithography technique.
[Patent Document 1] Japanese Patent Application Laid-Open No. 2002-115071 [Patent Document 2] Japanese Patent Application Laid-Open No. 2001-64775 [Patent Document 3] Japanese Patent Application Laid-Open No. 2003-31116. In the arc discharge method and the vacuum plasma method, manufacturing equipment is complicated because equipment for evacuating the inside of the apparatus is required, and equipment costs and manufacturing costs are high. Furthermore, in the arc discharge method, it is difficult to produce and grow a nanostructured carbon material directly on a substrate having a flat surface, and even if possible, it is limited to a local range and can be formed directly and uniformly on a large area substrate. Nearly impossible. In addition, since the thermal CVD process is performed at a very high temperature of 600 ° C. or higher, when the nanostructured carbon material is directly formed on the substrate, the base material can be a ceramic or quartz glass that can withstand high temperatures. It is difficult to use a material that is deformed even at a temperature of 500 ° C. or lower, such as general glass or plastic such as soda glass, which is conventionally used as a substrate material. . Therefore, development of a manufacturing technique effective for producing an electron emission source of the FED is awaited.
This invention is made | formed in view of said situation, The objective is to provide the manufacturing method which forms a nanostructure carbon material on various base materials easily, and obtains an electron emission source.

The object of the present invention can be achieved by the following constitution.
(Structure 1) A method of manufacturing an electron emission source, wherein at least a conductive layer forming step of forming a conductive layer on a substrate, an insulating layer forming step of forming an insulating layer on the conductive layer, and a gate on the insulating layer A gate layer forming step of forming a layer, a nanostructured carbon material layer forming step of forming a nanostructured carbon material layer on the conductive layer, the conductive layer forming step, the nanostructured carbon material layer forming step, and the insulating layer An electron emission source manufacturing method, wherein at least one of the forming step and the gate layer forming step is performed by an atmospheric pressure plasma method.
(Configuration 2) The method of manufacturing an electron emission source according to Configuration 1, wherein the nanostructure carbon material layer forming step is performed by an atmospheric pressure plasma method.
(Configuration 3) The nanostructured carbon material layer forming step includes a metal fine particle attaching step for attaching metal fine particles on the conductive layer, and the nanostructured carbon material layer forming step includes the metal fine particle attached to the conductive layer. 3. The method of manufacturing an electron emission source according to Configuration 2, wherein a nanostructured carbon material layer is formed on the layer.
(Structure 4) The method of manufacturing an electron emission source according to Structure 3, wherein the metal fine particle attaching step for attaching metal fine particles on the conductive layer is performed by an atmospheric pressure plasma method.
(Structure 5) The method of manufacturing an electron emission source according to Structure 1, wherein the conductive layer forming step is performed by an atmospheric pressure plasma method.
(Structure 6) The method of manufacturing an electron emission source according to structure 1, wherein the insulating layer forming step is performed by an atmospheric pressure plasma method.
(Structure 7) The method of manufacturing an electron emission source according to Structure 1, wherein the gate layer forming step is performed by an atmospheric pressure plasma method.
(Configuration 8) The method of manufacturing an electron emission source according to Configuration 1, further comprising a cleaning step, wherein the cleaning step is performed by an atmospheric plasma method.
(Configuration 9) In the atmospheric pressure plasma method, a gas containing at least a discharge gas is introduced between opposing electrodes under a pressure of atmospheric pressure or near atmospheric pressure, and a high frequency voltage is applied between the electrodes to discharge the discharge gas. The method of manufacturing an electron emission source according to Configuration 1, wherein the high frequency voltage is in a range of 0.5 kHz to 100 MHz.
(Structure 10) A method of manufacturing an electron emission source according to Structure 9, wherein 50% by volume or more of the gas introduced between the electrodes is argon gas or nitrogen gas.
(Configuration 11) An electron emission source manufactured by the manufacturing method according to any one of configurations 1 to 10.
(Structure 12) A planar image device using the electron emission source according to Structure 11 as a field emission cold cathode.

FIG. 1 is a schematic cross-sectional view for explaining the configuration of an FED, which is an example of a planar image device that uses an electron emission source according to an embodiment of the present invention as a field emission cold cathode.
FIGS. 2 (a) to 2 (k) are schematic cross-sectional views for explaining a patterning step of patterning a nanostructured carbon material by lithography on a substrate according to an embodiment of the present invention.
FIG. 3 is a cross-sectional view showing an example of a gas introduction part and an electrode part in a plasma jet type apparatus of the atmospheric pressure plasma discharge treatment apparatus used in the present invention.
FIG. 4 is a cross-sectional view showing an example of a direct type apparatus in the atmospheric pressure plasma discharge treatment apparatus used in the present invention.
FIG. 5 is a schematic cross-sectional view of a production apparatus for forming metal fine particles in an atmospheric pressure plasma discharge treatment apparatus used in the present invention.
FIG. 6 is a cross-sectional view showing another example of the direct type apparatus in the atmospheric pressure plasma discharge treatment apparatus used in the present invention.
FIG. 7 is a cross-sectional view showing an example of an apparatus in which a cleaning film is provided in a direct type apparatus among atmospheric pressure plasma discharge treatment apparatuses used in the present invention.

The present invention uses an atmospheric pressure plasma method for generating a discharge plasma by introducing a mixed gas containing a discharge gas and a source gas between opposing electrodes and applying a high-frequency voltage under atmospheric pressure or a pressure near atmospheric pressure. Thus, a nanostructured carbon material is formed on a base material on which a conductive layer is formed to manufacture an electron emission source. Examples of the nanostructured carbon material include carbon nanotubes, carbon nanofibers, and graphite nanofibers.
In the present invention, the atmospheric pressure or the pressure in the vicinity thereof is about 20 kPa to 110 kPa, and preferably 93 kPa to 104 kPa. In the present invention, the high frequency means one having a frequency of at least 0.5 kHz. Preferably it is 5-100MHz, More preferably, it is 50kHz-50MHz. Further, as described in Japanese Patent Application Laid-Open No. 2003-96569, the electrodes may be applied at different frequencies to the opposing electrodes.
The discharge treatment apparatus used in the atmospheric pressure plasma method according to the present invention applies a high-frequency voltage between a pair of opposed electrodes, at least one of which is coated with a dielectric, and discharges between the opposed electrodes. At least a discharge gas introduced between them and a raw material gas for forming a desired thin film or structure are activated, and a base material that is left stationary or transferred between the counter electrodes is an activated raw material gas To form a thin film or a structure on the substrate (hereinafter, this method is referred to as a direct method). As another method, a base material is placed in the vicinity of the opposite electrodes in the same manner as described above, and the discharge gas introduced between the opposite electrodes is excited or activated, and the jet is discharged outside the opposite electrodes. The raw material gas is mixed and mixed in the vicinity of the blowing base material and exposed to the base material (which may be stationary or transferred) in the vicinity of the counter electrode, so that the nanostructured carbon is formed on the base material. There is a jet type apparatus for forming a material (hereinafter, this type is called a plasma jet type). The atmospheric pressure plasma discharge treatment apparatus includes a gas supply unit that supplies a discharge gas and a source gas between the counter electrodes, and preferably further includes an electrode temperature control unit that controls the temperature of the electrode.
In the present invention, the gas supplied between the counter electrodes (discharge space) includes at least a discharge gas that is excited by an electric field and a gas that receives the energy and enters a plasma state or an excited state to form a nanostructured carbon material. It is out. In other words, the gas that forms the nanostructured carbon material is a source gas that receives energy from the discharge gas, becomes excited and becomes active, and chemically deposits on the substrate to form the nanostructured carbon material. That is. Since the substance itself that forms the nanostructured carbon material becomes active in this manner, a highly structured nanostructured carbon material is deposited on the substrate without heating the substrate to a high temperature. An additional gas for promoting the reaction may be added. Source gases include hydrocarbon gases such as methane, fluorine-based carbonized compounds, carbon oxides such as CO ₂ and CO, alcohols, ketones, amides, sulfoxides, ethers and esters. Preferred are hydrocarbon gas and fluorine-based carbonized compound. An additive gas may be contained depending on the type of source gas. Examples of the additive gas include hydrogen gas, water vapor, hydrogen peroxide gas, gas such as carbon monoxide gas, fluorocarbon and fluorohydrocarbon, among which hydrogen gas, fluorocarbon and fluorocarbon Water vapor is preferred.
The discharge gas is a gas capable of causing the material forming gas to be deposited on the base material and capable of causing a uniform discharge within the discharge surface, and itself functions as a medium for transferring energy. Examples of the discharge gas include nitrogen gas, rare gas, and hydrogen gas, and these may be used alone as a discharge gas or may be used in combination. Examples of the rare gas include helium, neon, argon, krypton, xenon, and radon, which are Group 18 elements of the periodic table. In the present invention, argon and nitrogen are preferable as the discharge gas from the viewpoint of mass production cost, and 50% by volume or more of the gas introduced into the discharge space is preferably argon gas and / or nitrogen gas. The amount of discharge gas is preferably 90 to 99.9% by volume with respect to the total amount of gas supplied to the discharge space.
From the viewpoint of uniformly depositing the raw material gas on the substrate by discharge plasma treatment, the content in the mixed gas is preferably 0.01 to 10% by volume, more preferably 0.01 to 1%. % By volume. Moreover, it is preferable to supply to discharge space with respect to discharge gas at 0.01-50 volume%.
The temperature at which the nanostructured carbon material is formed on the substrate using the atmospheric pressure plasma method is preferably 400 ° C. or less, more preferably 300 ° C. or less. In this way, by suppressing the rise in temperature when forming the nanostructured carbon material on the base material, for example, even a heat-resistant material such as glass or plastic can be used as the base material. Become.
Hereinafter, the present invention will be described in detail by embodiments, but the present invention is not limited to this, and the following description may include assertive expressions for terms and the like, It shows a preferable example in the present invention, and does not limit the meaning or technical scope of the term of the present invention.
FIG. 1 is a schematic cross-sectional view for explaining the configuration of an FED, which is an example of a planar image device that uses an electron emission source according to an embodiment of the present invention as a field emission cold cathode. The planar image apparatus shown in FIG. 1 includes an anode substrate 41 including an electron emission source 1 and a phosphor 42, and the electron emission source 1 includes a conductive layer 3, an insulating layer 4, and an insulating layer 4 formed on a base material 2. The gate layer 5 formed above, the nanostructured carbon material layer 8 formed on the conductive layer 3, and the like. An anode substrate 41 provided with a phosphor 42 is disposed facing the electron emission source 1, and the distance Da between the upper surface of the base material 2 and the lower surface of the anode substrate 41 is desirably Da = 200 μm to several mm. A number of holes (diameter: d = 10 to 20 μm) are formed in the gate layer 5, and several nanometers to several tens of volts are formed in the nanostructured carbon material layer 8 through a circuit formed in the conductive layer 3. A negative potential is applied (a positive potential of several V to several tens V is applied to the anode substrate 41 side, and a positive potential is applied to the gate layer 5), but the tip radius of the nanostructured carbon material layer 8 is 5 nm or less. Due to the small size, strong electric field concentration occurs at the tip portion, and electrons in the nanostructured carbon material layer 8 are emitted toward the anode substrate 41. The emitted electrons collide with the phosphor 42 provided on the anode substrate 41 side to cause the phosphor 42 to emit light. The substrate 2 may be any of insulating, conductive, and semiconductive, for example, quartz glass, sapphire, crystallized transparent glass, pyrex (R) glass, soda lime glass, low soda glass, lead alkali silicate glass, borosilicate. It may be a glass material such as acid glass, or an inorganic material such as a ceramic material such as alumina, zirconia, titania, silicon nitride, silicon carbide, gadolinium, gallium, or garnet, or may be a resin material (organic material) described below. Various materials can be used as the resin material as long as they exhibit heat resistance. For example, polyimide, fluororesin, polyetheretherketone (PEEK), polyethersulfone can be used as a material having a heat resistant temperature of 250 ° C. or lower. (PES), polyparabanic acid resin, polyphenylene oxide, polyarylate resin, and epoxy resin can be used. Among these, polyimide can be preferably used.
Also, ABS resin, polycarbonate, polypropylene, acrylic resin, styrene resin, polyarylate, polysulfone, polyethersulfone, epoxy resin, poly-4-methylpentene-1, fluorinated polyimide, phenoxy resin, polyolefin resin, Nylon resin, polyamide resin, polyamideimide resin, tetrafluoroethylene resin (PTFE), tetrafluoroethylene-perfluoroalkoxyethylene copolymer (PFA), tetrafluoroethylene-hexafluoropropylene copolymer (FEP) , High temperature nylon resin, polyphenylene sulfide resin (PPS), trifluoroethylene chloride resin (CTFP), modified phenol resin, polyethylene terephthalate resin (PET), polybutylene terephthalate resin (PBT), polyether ether ketone Heat-resistant slides that have slidability and wear resistance as well as heat resistance by adding fillers such as glass fiber, glass beads, graphite, carbon fiber, fluororesin, molybdenum disulfide, and titanium oxide to resins such as PEEK A moving resin is used. For example, graphite-containing polyimide resin, graphite-containing nylon resin, PTFE-containing acetal resin, PTFE-containing phenol resin, and the like. In addition, as a material having a heat resistant temperature of 250 ° C. or more, a filler such as glass fiber, glass bead, graphite, carbon fiber, fluororesin, molybdenum disulfide, titanium oxide or the like on a base resin such as polyimide resin, polyamide resin, polyamideimide resin, etc. Is also suitable as a material having a continuous use temperature of 250 ° C. or higher. These resin base materials and composite base materials are used as plate-type or film-type base materials.
FIGS. 2 (a) to 2 (k) are schematic cross-sectional views for explaining a patterning process for patterning a nanostructured carbon material by lithography according to the embodiment of the present invention. FIGS. 2 (a) to 2 (k) are respectively a substrate cleaning step, a conductive layer forming step, an insulating layer forming step, a gate layer forming step, an opening forming step, and a sacrificial layer applying step. , Exposure process, development process, metal fine particle adhesion process, nanostructure carbon material application process, and sacrificial layer removal process.
FIG. 3 is a cross-sectional view showing an example of a gas introduction part and an electrode part in a plasma jet type apparatus of the atmospheric pressure plasma discharge treatment apparatus used in the present invention. Processes that can be processed using the processing apparatus shown in FIG. 3 are the substrate cleaning process and the insulating layer forming process shown in FIGS. 2 (a) to 2 (k). In FIG. 3, two pairs of electrodes 21a and 21b connected to the first power source 11 are provided in parallel. At least one of the electrodes is covered with a dielectric 22, and a high frequency voltage is applied to the space 23 formed between the electrodes by the first power supply 11. The electrodes 21a and 21b have a hollow structure 24 inside, and during discharge, water, oil, etc. can be used to waste heat generated by the discharge, and heat exchange can be performed to maintain a stable temperature. ing. In each of the electrodes described above, examples of the metal base material include metals such as silver, platinum, stainless steel, aluminum, and iron, but stainless steel and titanium are preferable from the viewpoint of processing. The dielectric is preferably an inorganic compound having a relative dielectric constant of 6 to 45, and examples of such a dielectric include ceramics such as alumina and silicon nitride, silicate glass, and borate. There are glass lining materials such as glass. Among these, a dielectric provided by spraying alumina is preferable. Moreover, it is preferable to perform a sealing process as needed. The distance between the opposing electrodes (electrode gap) is determined in consideration of the thickness of the dielectric provided on the conductive metallic base material, the thickness of the substrate, the magnitude of the applied voltage, the purpose of using plasma, etc. However, the shortest distance between the dielectric surface when the dielectric is provided on one of the electrodes and the surface of the conductive metallic base material, and the distance between the dielectric surfaces when the dielectric is provided on both of the electrodes In any case, the thickness is preferably 0.1 to 20 mm, particularly preferably 0.5 to 2 mm from the viewpoint of uniform discharge. Here, the gas 31 containing the discharge gas is supplied to the space 23 through the flow path 34 by a gas supply means (not shown), and when a high frequency is applied to the space 23, the discharge is performed and the gas 31 is turned into plasma. The The plasma-ized gas 31 is ejected into the mixed space 25 with the source gas.
On the other hand, the mixed gas 32 containing the raw material gas supplied by the gas supply means (not shown) passes through the flow path 35 and is similarly transported to the mixing space 25 where it is merged with the plasma discharge gas and mixed. Sprayed up. The source gas in contact with the plasma mixed gas is activated by the plasma energy to cause a chemical reaction, and a desired thin film or structure is formed on the substrate 2. The apparatus of this example has a structure in which the mixed gas 32 containing the source gas is sandwiched or surrounded by the activated discharge gas.
The moving stage 27 has a structure capable of reciprocating scanning or continuous scanning, and is structured such that heat exchange can be performed in the same manner as the electrodes so that the temperature of the substrate can be maintained as necessary. Further, a mechanism 70 for exhausting the gas blown onto the base material can be provided as necessary. Thereby, unnecessary complex products generated in the space can be quickly removed from the discharge space and the substrate. The substrate to be used is not limited to a plate-shaped planar substrate, and three-dimensional objects and film-like substrates can be employed by changing the structure of the moving stage.
FIG. 4 is a sectional view showing an example of a direct type apparatus in the atmospheric pressure plasma discharge treatment apparatus used in the present invention. Processes that can be processed using the processing apparatus shown in FIG. 4 are the conductive layer forming process, the gate layer forming process, and the nanostructured carbon material applying process shown in FIGS. 2 (a) to 2 (k). It is. In this example, the moving stage 27 constitutes one opposing electrode, and the two electrodes 21 a and 21 b connected to the power source 11 are provided side by side so as to be parallel to the moving stage 27. Each or at least one of the electrodes 21a and 21b and the moving stage 27 is covered with a dielectric 22, and a high frequency voltage is applied to the space 23 formed between the electrodes 21a and 27 and between the electrodes 21b and 27 by the electrode 11. It is supposed to be done. The electrodes 21a, 21b and 27 have a hollow structure 24 so that the heat generated by the discharge is discharged by water, oil, etc. during discharge, and heat exchange can be performed to maintain a stable temperature. It has become. Here, a gas 31 containing a discharge gas is mixed and mixed into the mixing space 25 via a flow path 34 and a mixed gas 32 containing a raw material gas via a flow path 35 by a gas supply means (not shown). The mixed gas passes between the electrodes 21a and 21b and is supplied to the space 23 between the electrodes 21a and 27 and between the electrodes 21b and 27. When a high frequency is applied to the space 23, a discharge is generated, so that the discharge gas is plasma. It becomes. The source gas is activated and causes a chemical reaction by the energy of the discharge gas converted into plasma, and a desired thin film or structure is formed on the substrate 2.
FIG. 5 is a schematic cross-sectional view of a manufacturing apparatus for forming metal fine particles in an atmospheric pressure plasma discharge treatment apparatus used in the present invention. By changing the electrodes 21a and 21b in FIG. 4 to sputter targets such as iron, chromium and nickel, the manufacturing apparatus shown in FIG. 5 is obtained. The other structure is the same as that of the manufacturing apparatus of FIG. In the manufacturing apparatus shown in FIG. 5, the electrode 27 requires the dielectric 22, and the gap D1 between the electrodes 21a and 21b and the substrate 2 is preferably 5 mm or less. In addition, the particle size of the metal fine particles produced by the manufacturing apparatus is 10 to 100 nm. Further, it is preferable to use a metal fine particle layer obtained by this metal fine particle adhesion step having a thickness of 10 nm to 1 μm.
FIG. 6 is a view showing another example of the direct type apparatus in the atmospheric pressure plasma discharge treatment apparatus used in the present invention. It is preferable to use an inexpensive gas such as argon gas or nitrogen gas as the discharge gas because the cost of forming the nanostructured carbon material can be reduced. As one method for generating high-energy plasma with such a gas, There is a method of applying different frequencies to the opposing electrodes as in the atmospheric pressure plasma discharge apparatus in the figure.
Further, the frequency of the first power supply 11 is preferably 200 kHz or less, and the lower limit is preferably about 1 kHz. On the other hand, the frequency of the second power supply 12 is preferably 800 kHz or more. The higher the frequency of the second power source 12, the higher the plasma density. The upper limit is preferably about 200 MHz. These electric field waveforms may be sine waves or pulse waves, but are preferably sine waves. The discharge output of the voltage introduced between the electrodes (discharge space) is preferably 1 W / cm ² or more, more preferably 1 to 50 W / cm ² . In the apparatus shown in FIG. 6, a mixed gas 32 containing a raw material gas indicated by a white arrow and a gas 31 containing a discharge gas indicated by a black arrow are mixed and flowed onto the substrate 2. The mixed gas that has collided with the base material 2 moves in the discharge space 25 along the surface of the base material 2 and is then discharged to the outside.
Between the electrodes 21a and 21b and the first power source 11, a first filter 18a is installed so that the current from the first power source 11 flows toward the electrodes 21a and 21b, and the current from the first power source 11 passes therethrough. It is designed to make it difficult for the current from the second power source 12 to pass through. A second filter 18b is installed between the moving stage electrode 27 and the second power source 12 so that the current from the second power source 12 flows toward the moving stage electrode 27. It is designed to make it difficult to pass current and to easily pass current from the first power supply 11. As the first filter 18a, a capacitor of several tens to several tens of thousands of pF or a coil of about several μH can be used according to the frequency of the second power source. As the second filter 18b, a coil of 10 μH or more is used according to the frequency of the first power supply, and it can be used as a filter by grounding through these coils or a capacitor.
FIG. 7 is a cross-sectional view showing an example of an apparatus in which a cleaning film is provided in a direct type apparatus among atmospheric pressure plasma discharge treatment apparatuses used in the present invention. Processes that can be processed using the processing apparatus shown in FIG. 7 are the gate layer and insulating layer etching process and metal fine particle adhesion process shown in FIGS. 2 (a) to 2 (k). A pair of electrodes 21a and 21b are arranged opposite to the upper surface of the moving stage 27 with a gap D2. Moreover, the gas supply part 60 which ejects gas toward the clearance gap between a pair of electrodes 21a and 21b is arrange | positioned in the position facing the said clearance gap. Thus, the gap becomes a flow path 29 for supplying gas to the discharge space. The gas supply unit 60 includes a nozzle body 61 having a gas channel formed therein, and a gas ejection unit 62 that projects from the nozzle body 61 toward the channel 29 and ejects gas through the gas channel. And are provided.
A cleaning film 53 for preventing the pair of electrodes 21a and 21b from being soiled is provided so as to be conveyed continuously or intermittently by the film transport mechanism 50 while being in close contact with the electrodes 21a and 21b. The film transport mechanism 50 is provided with a film guide roller 51 for guiding the cleaning film 53 in the vicinity of the gas supply unit 60. An unillustrated unwinding roller or original winding of the cleaning film 53 is provided on the upstream side of the film guide roller 51. Further, a winding unit (not shown) for winding the cleaning film 53 via the other film guide roller 32 is provided farther from the film supply roller 51 than the gas supply unit 60. . The width dimension of the cleaning film 53 is preferably set so that both ends protrude 1 to 100 mm from both ends of the electrodes 21a and 21b. Thereby, the cleaning film 53 becomes larger than the discharge space, and contamination of the electrodes 21a and 21b can be prevented without being exposed to the discharge plasma. As described above, since the cleaning film 53 and the nozzle body 61 are in contact with each other, the space from the gas supply unit 60 to the flow path 29 is partitioned by the cleaning film 53 so that the gas flows. It can prevent flowing out of the path 29.
Next, referring back to FIGS. 2 (a) to 2 (k), each step of patterning by lithography will be described in detail based on examples.

In the substrate cleaning step shown in FIG. 2 (a), nitrogen gas in which 5% by volume of oxygen gas is mixed is blown onto the surface of the substrate 2 using the apparatus shown in FIG. A high frequency (sine wave or pulse wave) of 100 MHz is also applied for 10 seconds under a high pressure of 5 kV. An inert gas such as helium or argon may be used instead of the nitrogen gas, and hydrogen, a fluorine compound, water, or the like may be used instead of the oxygen gas.
In the conductive layer forming step shown in FIG. 2 (b), 0.1 volume% aluminum acetylacetonate gas and 4 volume% hydrogen gas are applied to the surface of the substrate 2 using the apparatus shown in FIG. The mixed argon gas was blown and a high frequency of 13.56 MHz and 10 W / cm ² was applied for 300 seconds to form an aluminum film having a thickness of 300 nm as the conductive layer 3. An inert gas such as helium or nitrogen gas may be used instead of the argon gas, and the frequency of the high frequency may be 1 kHz to 100 MHz. The conductive layer 3 may be any material having conductivity, and in addition to aluminum, molybdenum, tantalum, tungsten, chromium, nickel, copper, or the like can be used. Further, iron, cobalt, rhodium, palladium, platinum, lanthanum, cerium and the like used as the catalyst material for the nanostructured carbon material can also be used.
In the insulating layer forming step shown in FIG. 2 (c), 0.2 vol% tetraethoxysilane gas and 10 vol% oxygen gas are mixed on the surface of the substrate 2 using the apparatus shown in FIG. Nitrogen gas was blown and a high frequency of 80 kHz and 7 kV was applied for 150 seconds to form a 3 μm thick SiO 2 film as the insulating layer 4. An inert gas such as helium or argon gas may be used instead of the nitrogen gas, and the frequency of the high frequency may be 1 kHz to 100 MHz. The material used for the insulating layer 4 is preferably a thermally stable substance, and is made of, for example, a metal or metalloid oxide or nitride, a chalcogenide, a fluoride, a carbide, or a mixture thereof. _SiO 2 _{Specifically, SiO, Al 2 O 3,} GeO 2, In 2 O 3, Ta 2 O 5, TeO 2, TiO 2, MoO 3, WO 3, ZrO 2, Si 3 N 4, AlN, BN , TiN, ZnS, CdS, CdSe, ZnSe, ZnTe, AgF, PbF ₂ , MnF ₂ , NiF ₂ , SiC, or a simple substance or a mixture thereof is used. The insulating layer 4 has a thickness in the range of 0.2 to 10 μm, preferably 1 to 2 μm.
In the gate layer forming step shown in FIG. 2 (d), 0.1 volume% aluminum acetylacetonate gas and 4 volume% hydrogen gas are applied to the surface alkoxide of the substrate 2 using the apparatus shown in FIG. A high frequency gas of 13.56 MHz and 10 W / cm ² was applied for 120 seconds to form an aluminum film having a thickness of 300 nm as the conductive layer 3. An inert gas such as helium or nitrogen gas may be used instead of the argon gas, and the frequency of the high frequency may be 1 kHz to 100 MHz. The CVD material may be an organometallic compound having another conductive metal element, chloride, or the like. As the material of the gate layer 5, the same material as that of the conductive layer 3 can be used.
In the etching process of the gate layer and the insulating layer shown in FIG. 2 (e), in order to etch the gate layer first, the gate layer is patterned by lithography technique, and then the apparatus shown in FIG. A mixed gas containing 0.1% by volume of chlorine gas was introduced, applied at 80 kH and 7 kV, etched for 150 seconds, and then the substrate was washed with pure water to remove residual chlorine. Subsequently, in order to etch the insulating layer, the insulating layer is patterned by a lithography technique, and using the apparatus shown in FIG. 7, a mixed gas containing 41% by volume of a fluorocarbon gas is introduced into the argon gas at 80 kH. Applied and etched for 150 seconds. As a result, the opening 81 was formed in the insulating layer 4 and the gate layer 5 to expose the conductive layer 3. An inert gas such as helium or argon gas may be used instead of the nitrogen gas, and the frequency of the high frequency may be 1 kHz to 100 MHz. As the etching material, other materials, for example, in the case of aluminum, a chlorine-based compound, bromine gas, bromine-based compound, or the like may be used. Further, the insulating film may be made of fluorine gas, oxygen gas, hydrogen gas, or the like as necessary. In addition, a wet etching method can be used for the etching process.
In the sacrificial layer (mask layer) film forming step shown in FIG. 2 (f), the mask layer 6 is formed on the conductive layer 3 exposed on the bottom surface of the formed opening 81 by photolithography. Therefore, the mask layer 6 covers the surface of the gate layer 5, the cross section (side surface of the opening) of the gate layer 5 and the insulating layer 4, and the exposed surface of the conductive layer 3 (bottom surface of the opening). As the mask layer 6, a commercially available resist or polyimide may be applied to the surface and cross section of the gate layer 5, the cross section of the insulating layer 4, and the surface of the conductive layer 3, and can be deposited by spin coating, dip, extrusion coating, or the like. . The film thickness of the mask material 6 along the opening is set to 0.1 μm or more and 5 μm or less. When the thickness of the mask material is 0.1 μm or less, the mask material is too thin, so that the etching solution is difficult to penetrate the entire substrate, and the emitter material deposited on the upper layer can be removed by lift-off described later. It becomes difficult. Further, when the thickness of the mask material is 5 μm or more, the electron emission characteristics are remarkably deteriorated as will be described later. For these reasons, the film thickness of the mask material 6 deposited on the creeping surface of the opening is 1 μm.
In the exposure step shown in FIG. 2 (g), the mask layer 6 is exposed by photolithography. Further, a baking process may be provided as appropriate in order to cure the mask material.
In the developing process shown in FIG. 2 (h), the exposed portion of the mask layer 6 is dissolved by photolithography to form the opening 91 and the conductive layer 3 is exposed.
In the metal fine particle attaching step shown in FIG. 2 (i), an electrode (described later) facing the base material 2 is replaced with an iron electrode (not shown) using the apparatus shown in FIG. The gap was set to 1 mm, and argon gas was introduced between the electrode and the substrate 2 to form a film for 60 seconds by applying a high frequency of 13.56 MHz and 4 W / cm ² . As a result, iron fine particles having a particle diameter of ˜50 nm are deposited on the exposed aluminum film of the conductive layer 3 and the mask layer 6 to form a metal fine particle layer (iron fine particle layer) 7 having a thickness of ˜0.1 μm. It was.
In the nanostructured carbon material application step shown in FIG. 2 (j), the electrode shown in FIG. 4 is used to replace the electrode facing the substrate 2 with an electrode (not shown) using an alumina dielectric, Argon gas mixed with 0.1% by volume of methane gas and 3% by volume of hydrogen gas was introduced between the electrode 2 and the base material 2 with a gap of 2 mm between the material 2 and 600 when high frequency 13.56 MHz was applied. Second film was formed. As a result, nanofiber-like nanostructured carbon material grew on the fine iron particle layer 7 as catalyst fine particles, and the nanostructured carbon material layer 8 was formed. The nanostructured carbon material can be controlled to grow into a graphite-like structure by changing not only the nanofibers but also the plasma application conditions, gas conditions, and pressure conditions in the chamber.
In the sacrificial layer removal step shown in FIG. 2 (k), the mask layer 6 is removed together with unnecessary portions of the iron fine particle layer 7 and the nanostructured carbon material layer 8 by lift-off to form nanostructured carbon that is a field emission electron emission source. The material layer 8 could be formed.
The produced field emission electron emission source was bonded to an anode electrode of a type in which a phosphor layer of RGB three colors was provided on a glass support and coated on the ITO layer with a spacer having a thickness of 500 μm. Then, it was made to evacuate until it became about 10 Pa-6 Pa from the vacuum quotation hole provided previously, and it was made to close. As a result of driving the field emission type electron-emitting devices manufactured as described above by the simple matrix method, it was possible to obtain high-definition images. Further, the durability could be used for 1000 hours or more, and there was no problem.
In the present invention, as described above, in order to facilitate the formation of the nanostructured carbon material, a metal fine particle adhesion process is performed in which metal fine particles are previously deposited on the substrate, and then the metal fine particles are adhered to the substrate. It is preferable to form a nanostructured carbon material. As the metal used in the metal fine particle adhesion step, various metals that exhibit a catalytic action in the formation of graphite and the vapor phase decomposition growth of carbon nanotubes can be used. Specifically, for example, iron groups such as Ni, Fe and Co, platinum groups such as Pd, Pt and Rh, rare earth metals such as La and Y, transition metals such as Mo and Mn, and metal compounds thereof Any one of these or a mixture of two or more thereof can be used. In the metal fine particle attaching step, any method may be used as long as the metal fine particles can be attached on the substrate. However, it is preferably performed by an atmospheric pressure plasma method, and in this case, a simple apparatus configuration is applied to the substrate. Metal fine particles can be attached. In addition, the method of attaching metal fine particles on a base material using an atmospheric pressure plasma method is roughly classified into a CVD method and a sputtering method. As described above, the sputtering method may use a target of each metal. In the case of the CVD method, a volatile organometallic compound such as an alkoxide or a betadiketone metal complex can be used as a raw material. These materials are gasified using a commercially available vaporizer, evaporator, etc., diluted with discharge gas, additive gas, etc., and introduced into the plasma space.
In the method of the present invention, since it is not necessary to raise the temperature when forming the nanostructured carbon material, it is possible to use a base material made of a material such as general soda glass or plastic. Therefore, for example, in the case of manufacturing an electron emission source for field emission display (FED), which is demanded for mass production in the future, this is a suitable method capable of forming a nanostructured carbon material on a glass substrate or a plastic substrate. In addition to displays, field emission is expected to have various applications such as electron beam sources and micro vacuum tubes.

  According to the present invention, a nanostructured carbon material and an electron emission source formed on the substrate can be efficiently and efficiently simultaneously formed on a large-area substrate at a lower substrate temperature (around 400 ° C.) than in the prior art. In addition, the nanostructured carbon material and the electron emission source can be manufactured with simple equipment that can be uniformly formed and does not require vacuum equipment or a high-temperature generator.

Claims (12)

A method of manufacturing an electron emission source, wherein a conductive layer forming step of forming a conductive layer on at least a substrate, an insulating layer forming step of forming an insulating layer on the conductive layer, and a gate layer formed on the insulating layer Including a gate layer forming step, a nanostructured carbon material layer forming step of forming a nanostructured carbon material layer on the conductive layer, the conductive layer forming step, the nanostructured carbon material layer forming step, the insulating layer forming step, and the At least one of the gate layer forming steps is performed by an atmospheric pressure plasma method at a temperature of 400 ° C. or lower and a discharge output of 1 to 50 W / cm ² . 2. The method of manufacturing an electron emission source according to claim 1, wherein the nanostructured carbon material layer forming step is performed by an atmospheric pressure plasma method. The nanostructured carbon material layer forming step includes a metal fine particle attaching step for attaching metal fine particles on the conductive layer, and the nanostructured carbon material layer forming step is performed on the conductive layer on which the metal fine particles are attached. 3. The method of manufacturing an electron emission source according to claim 2, wherein a structural carbon material layer is formed. 4. The method of manufacturing an electron emission source according to claim 3, wherein the metal fine particle attaching step of attaching metal fine particles on the conductive layer is performed by an atmospheric pressure plasma method. 2. The method of manufacturing an electron emission source according to claim 1, wherein the conductive layer forming step is performed by an atmospheric pressure plasma method. 2. The method of manufacturing an electron emission source according to claim 1, wherein the insulating layer forming step is performed by an atmospheric pressure plasma method. 2. The method of manufacturing an electron emission source according to claim 1, wherein the gate layer forming step is performed by an atmospheric pressure plasma method. The method of manufacturing an electron emission source according to claim 1 , further comprising a cleaning step, wherein the cleaning step is performed by an atmospheric plasma method. In the atmospheric pressure plasma method, a gas containing at least a discharge gas is introduced between opposing electrodes under atmospheric pressure or a pressure near atmospheric pressure, and a high frequency voltage is applied between the electrodes to bring the discharge gas into a plasma state. 2. The method of manufacturing an electron emission source according to claim 1 , wherein the frequency of the high-frequency voltage is in a range of 0.5 kHz to 100 MHz. 10. The method of manufacturing an electron emission source according to claim 9, wherein 50% by volume or more of the gas introduced between the electrodes is argon gas or nitrogen gas. The electron emission source manufactured with the manufacturing method of any one of Claims 1-10 . A planar image device using the electron emission source according to claim 11 as a field emission cold cathode.

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