JP4940392B2 - Method for producing carbon nanostructured material - Google Patents

Description

  The present invention relates to a cathode electrode of an electron source of a field emission display, an electron gun of a television, an electron gun of an X-ray generation source, or an STM (scanning tunnel microscope) or an AFM (atomic force microscope) for an SPM (scanning probe microscope). ) Or the like, a micro needle, or a carbon nanostructure material that is a carbon nanotube used for a manipulator probe.

  As a flat panel display, a liquid crystal display (LCD) or a plasma display (PDP) has been put into practical use. In recent years, a field emission display (FED) has attracted attention in addition to these (for example, see Non-Patent Document 1). ).

  FIG. 6 is a schematic configuration diagram illustrating a pixel of the field emission display. As shown in FIG. 6, the pixel of the display includes a cathode side having carbon nanofibers 103 or carbon nanotubes of a carbon nanostructure material, and an anode side having a phosphor 105. On the cathode side of the pixel, a cathode electrode (cathode electrode) 101 is provided on a glass substrate 100, and a single film of Fe, Co, Ni, Pt or the like or an alloy film containing them as a main component is formed on the cathode electrode 101. A catalytic metal film 102 is formed, and a plurality of carbon nanofibers 103 are formed on the cathode electrode 101 using the catalytic metal film 102 as a catalyst. On the anode side of the pixel, a phosphor 105 is provided on an anode electrode (transparent electrode) 104 disposed on the front side of the cathode electrode 101 by coating, and a glass substrate 106 is provided on the phosphor 105. The cathode side and the anode side are positioned such that the cathode electrode 101 and the anode electrode 104 have a predetermined gap, and the space between them is adjusted to a predetermined degree of vacuum.

  When a voltage of several kV is applied between the cathode electrode 101 and the anode electrode 104 by the power source 107, the electric field at the tip of the carbon nanofiber 103 is increased, and electrons are emitted from the tip by the tunnel effect and emitted. The electrons are accelerated and collide with the fluorescent material 105 through the anode electrode 104 in the front, and the fluorescent material 105 is excited to emit light of one of the three primary colors corresponding to the fluorescent material. In this way, a desired image of various colors in which the hues of the three primary colors are adjusted by a plurality of pixels is reproduced. In the figure, the equipotential surface of the carbon nanofiber is indicated by a dotted line.

  By the way, the multiple carbon nanofibers 103 on the cathode electrode 101 have a high density of fibers 103 and have a certain level of height. Even if the electric field strength of each fiber 103 is high, the electric field as a whole is large. As a result of the smoothing, the equipotential surface around the tip of each fiber 103 does not become an acute angle, and electrons are not easily emitted from the tip of the fiber 103 (this phenomenon is called the shielding effect). Further, as shown in FIG. 7, even if the heights of the carbon nanofibers 103 are slightly different, if the fibers 103 are densely packed, the equipotential surface at the tip of the fiber 103 does not become an acute angle, and electrons are emitted. It will not be done. In addition, the carbon nanofibers 103 may exist individually one by one, but generally a plurality of fibers 103 are often bundled (bundled state), in which case, as shown in FIG. Since a plurality of fibers 103 are entangled to form the tip portion, the electric field is similarly smoothed and the electron emission is inhibited.

  In view of the above, the present inventors have found that carbon nanofibers or carbon nanotubes of a carbon nanostructure material are not densely packed on a silicon substrate, so that carbon nanofibers or carbon nanotubes are separated from each other in a sparse state. Several years ago, an experimental study was conducted to grow a carbon film into a carbon nanostructure material by irradiating the surface of the substrate on which the carbon film was formed with an ion beam using a growth apparatus as shown in FIG. Is going from.

For example, a silicon substrate having a diameter of 4 inches is used as the substrate. First, a carbon film having a thickness of 0.1 to 3 μm is formed in advance on the surface of the silicon substrate by an arc ion plating method. The silicon substrate on which the carbon film is formed is mounted on the substrate stage 3 of the growth apparatus, the chamber 5 is closed, the inside of the chamber 1 is evacuated by the rotary pump 7 and then the turbo molecular pump 6, and the ultimate pressure is 1 × 10 ^−5. When reaching below Torr, argon gas is introduced into the ion source 2 using the mass flow controller 8, the ion source 2 is operated, and Ar ions are extracted at an accelerating voltage of 0.3 to 5 kV, about 220 μA / cm ^2. The surface of the substrate on the stage 3 is irradiated with argon ions at the above ion current density. Prior to ion irradiation, the substrate is heated to about 200 ° C. by the heater 4. The temperature range in which carbon nanofibers can be grown is from room temperature to 1200 ° C.

  When the above ion irradiation is performed for about 100 minutes, as shown in FIG. 2, a large number of minute conical projections (growth projections) 11 made of a carbon film are formed on the surface of the silicon substrate 10, and each of the projections. Nanocarbon grows on the top of 11, and carbon nanofibers 12 having a diameter of about several nm to several hundred nm and a length of 0.1 μm to 10 μm are formed one by one. Thus, the carbon nanofibers 12 can be obtained in a sparse state in which the carbon nanofibers 12 are separated from each other without being densely packed on the substrate 10.

  For probes such as STM (Scanning Tunneling Microscope) and AFM (Atomic Force Microscope) for SPM (Scanning Probe Microscope), carbon nanofibers are formed on the probe projections to configure the probe. There are things to do. As shown in FIG. 3, a large number of probe projections 13 such as SPM STM and AFM are formed in advance on the surface of the substrate 10 at intervals, and a carbon film is formed on the surface of the substrate 10 in that state. When the above ion irradiation is performed, the formation of the minute growth projections 11 is likely to occur selectively on the top of the projections 13 instead of the flat portion of the substrate 10. Nanocarbon grows on top of the surface. Thereby, the thin carbon nanofibers 12 can be formed one by one on the probe projection 13 on the substrate 10.

  The protrusion 13 has a height of about 0.1 to 50 μm and a bottom width of about 0.05 to 25 μm. In order to form the protrusion 13, a semiconductor processing method is used for the substrate 10. Specifically, after transferring the mask using photolithography, if it is a silicon substrate, it is etched with an alkaline solution such as KOH (potassium hydroxide) or TMAH (tetramethyl ammonium hydroxide) solution. . With other substrate materials, it is possible to form protrusions on the substrate using dry etching such as RIE (reactive ion etching) or IPC (inductively coupled plasma) etching.

In FIG. 3, reference numeral 14 denotes a through hole for separating the support portion holding the probe from the substrate 10. After forming the carbon nanofibers 12, the substrate 10 is cut at the through hole 14, and the probe protrusion 13 is formed. Are used to separate them individually. The separation through-hole 14 has a size of several tens of μm or more, and is formed in the substrate 10 using an alkaline solution or dry etching in the same manner as when the protrusions 13 are formed.
“Topics of Light”, “The Future of the Display Market”, published on August 5, 2002, Ministry of Economy, Trade and Industry, Technical Research Office, [Search April 28, 2004], Internet <URL: http: // www. oitda.or.jp/main/hw/hw01302-j.html>

As described above, when a carbon film formed on the surface of the substrate by the arc ion plating method is used for the growth of carbon nanofibers, the ion current density is about 220 μA / cm ² or more for a substrate having a diameter of 4 inches. Ion irradiation must be performed for about 100 minutes, and the ion current density is large. For this reason, a large current ion source is required to form carbon nanofibers or carbon nanostructures such as carbon nanotubes on a large substrate.

Such a problem has also been confirmed in the case where a carbon nanostructure material such as carbon nanofiber is grown from a carbon film formed by an arc deposition method, an ECR plasma CVD method, or the like. When a 4-inch diameter substrate coated with a carbon film by these methods is irradiated with ions under the conditions of an ion current density of about 220 μA / cm ² and an irradiation time of 100 minutes, a carbon nanostructure material can be grown. Therefore, in order to form a carbon nanostructure material on a large substrate, an ion source with a large current is required as well.

  The arc ion plating, the arc vapor deposition method, the ECR plasma CVD method, and the like are all film forming methods capable of obtaining a very dense and hard carbon film. Of these, the arc ion plating method and the arc vapor deposition method are conventionally mainly used for coating of tools, and the ECR plasma CVD method is mainly used for forming a protective film of a hard disk.

  Accordingly, an object of the present invention is to irradiate a substrate having a carbon film on the surface with ions, to grow one carbon nanofiber on the top of each microprotrusion formed on the surface of the substrate, and to form carbon on the substrate. When carbon nanostructure materials such as nanofibers and carbon nanotubes are obtained in a loose and sparse state, by selecting an appropriate carbon film to be formed on the surface of the substrate, the nanostructure material can be obtained by ion irradiation at a low current density. The object is to provide a method for producing a carbon nanostructure material that can be grown in a sparse state.

In order to solve the above-mentioned problems, the method for producing a carbon nanostructure material of the present invention includes applying a acrylonitrile-based, pitch-based or phenolic resin-based organic polymer solution to the surface of a substrate, and the substrate on which the organic polymer solution is applied. Is heated in a vacuum heating furnace to form a carbon film on the surface of the substrate, and the surface of the substrate on which the carbon film is formed is irradiated with an ion beam at a current density of 30 to 150 μA / cm ² in a vacuum chamber. The carbon nanostructure material is formed on the surface of the substrate in such a manner that one carbon nanostructure material, which is a carbon nanofiber or a carbon nanotube, is grown on the top of each of the many protrusions formed on the surface of the substrate. It is characterized by that.

  According to the present invention, the organic polymer solution is an acrylonitrile-based polymer solution, the polymer is applied to the surface of the substrate, and then the substrate is baked at a temperature of 200 to 400 ° C. in an oxygen-containing atmosphere. The coating film of the acrylonitrile-based polymer is pre-oxidized, and then the coating film is carbonized by baking the substrate at a temperature of at least 1000 ° C. in an inert atmosphere to form a carbon coating on the surface of the substrate. Can be formed. Alternatively, the organic polymer solution is a pitch solution, and the pitch-based solution is applied to the surface of the substrate, and then the substrate is heated in an inert gas atmosphere at a temperature of 350 to 450 ° C. to form a coating film of the pitch. A carbon film may be formed on the surface of the substrate by carbonization treatment. Alternatively, the organic polymer solution is a resol-type or novolac-type phenol resin solution, and the phenol resin solution is applied to the surface of the substrate and then cured by heating at a temperature of 150 ° C., and then the substrate is inerted. In this case, the coating film of the phenol resin may be carbonized by baking at a temperature of at least 1000 ° C. to form a carbon film on the surface of the substrate.

  Further, according to the present invention, at least one atom or ion of iron, cobalt, molybdenum, nickel, palladium and platinum is deposited on the surface of the substrate on which the carbon film is formed by a vacuum arc deposition source in a film thickness of 1 nm to 300 nm. The ion beam may be irradiated after vapor deposition or simultaneously with vapor deposition. Alternatively, after a carbon mixed film containing 0.1 to 50.0 atomic% of at least one of iron, cobalt, molybdenum, nickel, palladium, and platinum is deposited on the substrate surface by a vacuum arc deposition source, or simultaneously with the deposition. You may make it irradiate an ion beam.

  In the present invention, when forming a carbon nanostructure material such as carbon nanofiber or carbon nanotube by irradiating the surface of the substrate on which the carbon film is formed with an ion beam, the carbon film is coated with an organic polymer solution such as a polyacrylonitrile-based solution. Even if ion beam irradiation is performed at a reduced current density, a single carbon nanostructure material is grown on top of each of a large number of protrusions formed on the surface of the substrate. A carbon nanostructured material can be obtained on the surface. Therefore, a carbon nanostructure material can be formed on a large substrate without using a large current ion source.

  Further, at least one atom or ion of iron, cobalt, molybdenum, nickel, palladium and platinum is deposited on the substrate surface with a film thickness of 1 nm to 300 nm by a vacuum arc deposition source, or at least one of these metal elements. When a carbon mixed film containing 0.1 to 50.0 atomic percent of the seed is deposited and irradiated with an ion beam after the deposition or simultaneously with the deposition, the diffusion of carbon atoms is controlled by the metal fine particles. As a result, the growth of carbon nanostructure material can be controlled by controlling the formation speed of the protrusion, and the length, thickness, number of carbon nanostructure material can be adjusted. , And the density can be controlled.

  Hereinafter, embodiments of the present invention will be described. In the present invention, a carbon nanofiber or carbon nanotube of a carbon nanostructure material is formed on the top of each protrusion formed on the surface of the substrate by irradiating the surface of the substrate on which the carbon film is formed with an ion beam in a vacuum chamber. Are grown one by one to form a carbon nanostructure material in a sparse state on the surface of the substrate. In the present invention, in order to form a carbon nanostructure material in a sparse state on the substrate surface even when the ion beam irradiation current density is lowered, arc ion plating, arc vapor deposition, or ECR plasma CVD is performed on the substrate surface. The main feature is that the carbon film is formed by the organic polymer solution rather than by the above.

In the present invention, as the organic polymer solution, a material such as carbon fiber can be used , and an acrylonitrile-based, pitch-based, or phenolic resin-based solution is used.

  The acrylonitrile-based solution is a precursor (precursor) in which an acrylonitrile-based polymer is dissolved in an organic solvent and acrylic fibers can be obtained by spinning. The acrylonitrile-based polymer may be composed of a repeating unit composed of a repeating unit of an acrylonitrile monomer or an olefin monomer copolymerizable therewith. There are several known methods for producing acrylonitrile, but by an ammoxidation method (Sohio method) in which a methyl group is converted to a cyano group by oxidative reaction of propylene and ammonia in air. It is manufactured in large quantities industrially.

  Examples of the olefin monomer copolymerizable with acrylonitrile include acrylic acid, methacrylic acid and esters thereof, acrylamide, vinyl acetate, styrene, vinyl chloride, vinylidene chloride, maleic anhydride, N-substituted maleimide, butadiene, and isobrene. Etc. As the organic solvent for dissolving the acrylonitrile-based polymer, dimethylformaldehyde, dimethylacetamide, dimethylsulfoxide and the like can be preferably used. The ratio of the acrylonitrile polymer and the organic solvent is preferably 95 to 65% by weight of the organic solvent with respect to 5 to 35% by weight of the acrylonitrile polymer.

  This acrylonitrile-based solution is applied to the surface of the substrate in an amount such that the film thickness after carbonization is about 0.1 to 3 μm by a dropping method or a spinner, and then the substrate is placed in a heating furnace to be 200 to 200 in an oxygen-containing atmosphere. Baking is performed at a temperature of 400 ° C. for 3 to 4 minutes, and the acrylonitrile coating film is pre-oxidized (flame resistance). Next, the substrate is placed in a baking furnace and baked at a temperature of at least 1000 ° C. in an inert atmosphere such as nitrogen gas to carbonize the coating film to obtain a carbonized or carbonized carbon film on the surface of the substrate.

  Examples of the pitch-based solution include coal tar pitch and petroleum-based pitch. More specifically, coal-based coal tar, coal tar pitch, coal liquefaction, petroleum-based pitch, such as FCC oil, coker oil or their distillation residue, or naphthalene, anthracene are polycondensed with a catalyst or formalin derivative. A pitch produced by heating-vacuum distillation of an aromatic resin produced by reaction or an oligomer obtained by crosslinking formaldehyde with alkylbenzene in a strongly acidic catalyst can be preferably used.

  This pitch-based solution is applied to the surface of the substrate in such an amount that the film thickness after carbonization is about 0.1 to 3 μm, and the substrate is placed in a heating furnace at a temperature of 200 to 400 ° C. in an inert atmosphere for 1 to 6 hours. Baking and carbonizing the pitch coating film to obtain a carbon coating on the surface of the substrate.

  As the phenolic resin solution, a resol-type or novolac-type phenol resin can be preferably used, and these are used by dissolving in an organic solvent. Resol resin (resole type phenolic resin) is a liquid phenolic resin in which phenol and formaldehyde have a molar ratio of 1 in the presence of a basic catalyst (about 0.2-2%) such as sodium hydroxide, ammonia or organic amine. It is obtained by reacting under conditions of excess formaldehyde to 1-2. A novolak resin (novolak-type phenol resin) is an excess of phenol and formaldehyde in a molar ratio of 1: 0.7 to 0.9 in the presence of an acid catalyst (about 0.2 to 2%) such as oxalic acid. It can be obtained by reacting under the following conditions. These phenol resins are used by being dissolved in an organic solvent such as alcohol, ether, ester, ketone, amide or the like. Preferably, alcohols such as methanol, ethanol, butanol, and propanol are used.

  The phenolic resin solution is applied to the surface of the substrate in such an amount that the film thickness after carbonization is about 0.1 to 3 μm, and the substrate is placed in a heating furnace and heated at a temperature of 150 ° C. to form a phenolic resin coating film. Then, the substrate is baked at a temperature of at least 1000 ° C. in an inert atmosphere to carbonize the coating to obtain a carbon coating on the surface of the substrate.

  A silicon substrate or the like can be used as the substrate. After the carbon film is formed with the organic polymer solution on the surface of the substrate, the surface of the substrate is irradiated with an ion beam to form a carbon nanostructure material on the surface of the substrate. In the present invention, since the carbon film is formed using the organic polymer solution, the ion beam may be irradiated with a low current density, and the substrate is formed by the low current density ion beam irradiation as schematically shown in FIG. A large number of conical microprotrusions 11 having a height of about 0.5 μm to 2 μm made of a carbon film are formed on the surface of 10 at intervals of about 0.2 to 30 μm. 12 grows, and carbon nanofibers 12 are formed on the surface of the substrate 10 in a sparse state in which the lengths are not uniform and are separated one by one.

The current density of the ion irradiation, 30~150μA / cm ^2, preferably not good about 50~100μA / cm ^2. Although it does not limit as irradiation time, It is 3 to 150 minutes, Preferably it is about 15 to 100 minutes.

  According to the present invention, prior to irradiating the surface of the substrate with the ion beam, the vacuum arc deposition source is used to deposit at least one atom or ion of iron, cobalt, molybdenum, nickel, palladium, and platinum in a film thickness of 1 nm to 1 nm. Vapor deposition can be performed at 300 nm, or a carbon mixed film containing 0.1 to 50.0 atomic% of at least one of these metal elements can be deposited, and an ion beam can be irradiated after or at the same time as the deposition. According to this, since the diffusion of carbon atoms is controlled by the metal microparticles, it is possible to control the slow and fast formation of protrusions on the substrate, so the growth of carbon nanofibers can be controlled by controlling the formation speed. The length, thickness, number and density of the carbon nanofibers can be controlled. The same applies to the carbon nanotubes.

  FIG. 1 shows a growth apparatus used for forming a carbon nanostructure material in the present invention. The figure is shown except for a portion of the surrounding wall including the upper and lower walls and the front side of the chamber.

  This growth apparatus includes a chamber 5 having an arc plasma gun 1, an ion source 2, a substrate stage 3, and a heater 4. The chamber 5 includes a turbo molecular pump 6 and a rotary pump 7 connected in series to the turbo molecular pump 6. And an argon gas cylinder (not shown) is connected to the ion source 2 via a gas introduction mass flow controller 8. The arc plasma gun 1 and the ion source 2 are attached to the side wall at the opposite position of the chamber 5 at an angle of 45 ° with the central axis directed toward the substrate stage 3. The substrate stage 3 is installed at the lower center of the chamber 1 and can be tilted at an angle of ± 45 ° with respect to the horizontal so that the arc plasma gun 1 and the ion source 2 are positioned in the normal direction of the substrate placed on the stage 4. It has become. In the present invention, as described above, a polymer solution is applied to the surface of the substrate to form a carbon film, and the arc plasma gun 1 serves as an arc vapor deposition source for forming a vapor deposition catalyst film on the carbon film. use. In the figure, 9 is a Faraday cup (fluence measuring device) arranged in front of the argon ion outlet of the ion source 2.

A silicon substrate having a carbon film with a thickness of about 0.1 to 3 μm formed on the surface is mounted on the substrate stage 3 of the apparatus 1, the chamber 5 is closed, and the inside of the chamber 5 is evacuated by the rotary pump 7 and then the turbo molecular pump 6. Then, when the ultimate pressure reaches 1 × 10 ⁻⁵ Torr or less, argon gas is introduced into the ion source 2 using the mass flow controller 8 and the ion source 2 is operated to make Ar ions 0.3 to 5 kV. The substrate is heated at room temperature to about 1200 ° C. with the heater 4 on the stage 3 and is radiated with ions at a predetermined current density. Thereby, carbon nanofibers are formed on the surface of the substrate.

  The carbon nanofiber or carbon nanotube produced by the above production method can be applied as a cathode electrode of an electron source of a field emission display or a probe for a scanning probe microscope.

  When used as a cathode electrode of an electron source of a field emission display, each one can be formed in a sparse state without concentrating carbon nanofibers or carbon nanotubes on a substrate, thereby significantly improving electron emission efficiency. be able to.

  As a probe for a scanning probe microscope, carbon nanofibers or carbon nanotubes can be selectively grown on microprojections on a silicon substrate, so that carbon nanofibers or carbon nanotube probes are easily manufactured by batch processing. be able to. Therefore, it is possible to reduce the cost, and unlike the conventional bonding method, it is possible to grow directly from the protruding portion, so that a highly durable and high aspect ratio probe can be formed.

  Examples of the present invention will be described.

Example 1
As the organic polymer solution, an acrylonitrile polymer resist solution (AZ P1350 (viscosity: 4.2 cp) manufactured by Clariant Japan Co., Ltd.) is used, and this is dropped onto one whole surface of a 4-inch diameter silicon substrate with a dropper. Applied. This substrate was put into a chamber of an infrared heating type vacuum drying furnace (RTA-6 manufactured by ULVAC-RIKO), and when the pressure in the chamber became 1 to 2 Pa while evacuating with a rotary pump, the substrate was placed at 450 ° C. Baked for 15 minutes. In order to increase the film thickness obtained, this resist coating and baking process was repeated three times to form a baked carbon film of acrylonitrile with a film thickness of about 3 μm on the surface of the substrate.

Using the apparatus of FIG. 1, when ion irradiation was performed for 100 minutes at a current density of about 70 μA / cm ² on the surface of the substrate on which the acrylonitrile carbon film was formed, carbon nanofibers were scattered on the surface of the substrate. I was able to get it. FIG. 4 shows an SEM (scanning electron microscope) photograph of the obtained carbon nanofibers on the surface of the substrate.

Example 2
Example 1 was performed except that an iron-containing vapor deposition film was formed on the carbon film on the surface of the substrate before ion irradiation was performed on the surface of the substrate. As a result, carbon nanofibers similar to those in Example 1 could be obtained on the surface of the substrate by ion irradiation for 100 minutes at a current density of about 70 μA / cm ² .

Example 3
As the silicon substrate, the substrate in which the probe protrusions and the separation through holes shown in FIG. 3 were formed was used. The same resist solution as used in Example 1 was applied to the uneven surface on which the protrusions (15 μm in height) of the substrate were formed in a film thickness of 1 μm or less, and baked in the same manner as in Example 1 to obtain the surface of the substrate. A carbon film without unevenness was formed by filling the unevenness in the surface. Subsequently, while depositing a carbon mixed film containing 10 atomic% of iron on the surface of the substrate on which the carbon film is formed, ion irradiation is performed for 60 minutes at a current density of about 100 μA / cm ² for the probe on the substrate. Carbon nanofibers were formed on each of the protrusions by a growth protrusion, and carbon nanofibers could be efficiently formed with a lower current density and a shorter ion irradiation time. An SEM photograph of the carbon nanofibers on the obtained substrate surface is shown in FIG.

  The ion irradiation is not limited to Ar ions, and may be reactive ions including rare gas ions such as Ne (neon) and Xe (xenon), N (nitrogen), and C (carbon). .

The schematic block diagram which shows the growth apparatus used for manufacture of a carbon nanostructure material by the method of this invention. The schematic diagram which shows the substrate surface in which the carbon nanofiber was formed with the method of this invention. The schematic diagram which shows the board | substrate surface which formed the carbon nanofiber in the processus | protrusion for probe by the method of this invention. The SEM photograph which shows the carbon nanofiber of the substrate surface obtained in Example 1 of this invention. The SEM photograph which shows the carbon nanofiber of the substrate surface obtained in Example 1 of this invention. The schematic block diagram which shows the pixel of a field emission display. The figure which shows an example of the defect form of the carbon nanofiber of the substrate surface which comprises the pixel of FIG. It is a figure which shows the other example of the bad form of carbon nanofiber.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Arc plasma gun 2 Ion source 3 Substrate stage 4 Heater 5 Chamber 8 Mass flow controller 9 Faraday cup 10 Substrate 11 Growth protrusion 12 Carbon nanofiber 13 Protrusion for probe

Claims (6)

An organic polymer solution of acrylonitrile, pitch or phenol resin is applied to the surface of the substrate, and the substrate coated with the organic polymer solution is heat-treated in a vacuum heating furnace to form a carbon film on the surface of the substrate. The surface of the substrate on which the carbon film is formed is irradiated with an ion beam at a current density of 30 to 150 μA / cm ² in a vacuum chamber, and carbon nano-particles are formed on the tops of a number of protrusions formed on the surface of the substrate. A method for producing a carbon nanostructure material, comprising forming a carbon nanostructure material on a surface of the substrate in a mode in which one carbon nanostructure material that is a fiber or a carbon nanotube is grown.   The organic polymer solution is an acrylonitrile polymer solution. The polymer is applied to the surface of the substrate, and then the substrate is baked at a temperature of 200 to 400 ° C. in an oxygen-containing atmosphere to apply the acrylonitrile polymer. The film is pre-oxidized and then the substrate is baked at a temperature of at least 1000 ° C. in an inert atmosphere to carbonize the coating to form a carbon coating on the surface of the substrate. The manufacturing method of the carbon nanostructure material of Claim 1.   The organic polymer solution is a pitch solution, and the pitch-based solution is applied to the surface of the substrate, and then the substrate is heated in an inert gas atmosphere at a temperature of 350 to 450 ° C. to carbonize the coating film of the pitch. The carbon nanostructure manufacturing method according to claim 1, wherein a carbon film is formed on the surface of the substrate.   The organic polymer solution is a resol-type or novolac-type phenol resin solution, and the phenol resin solution is applied to the surface of the substrate and then cured by heating at a temperature of 150 ° C., and then the substrate is placed in an inert atmosphere. The method for producing a carbon nanostructure material according to claim 1, wherein the coating film of the phenol resin is carbonized by firing at a temperature of at least 1000 ° C to form a carbon film on the surface of the substrate.   Prior to irradiating the surface of the substrate on which the carbon film is formed with an ion beam, a film of at least one atom or ion of iron, cobalt, molybdenum, nickel, palladium and platinum is formed by a vacuum arc evaporation source. 5. The method for producing a carbon nanostructure material according to claim 1, wherein vapor deposition is performed at 1 nm to 300 nm, and irradiation with an ion beam is performed after the vapor deposition or simultaneously with the vapor deposition.   Prior to irradiating the surface of the substrate on which the carbon film is formed with an ion beam, at least one of iron, cobalt, molybdenum, nickel, palladium, and platinum is 0.1-50. 5. The method for producing a carbon nanostructure material according to claim 1, wherein a carbon mixed film containing 0 atomic% is deposited and an ion beam is irradiated after or simultaneously with the deposition.