Abstract: To provide a rectifying device equipped with a carrier transporter excellent in high frequency responsiveness and heat resistance, an electronic circuit using the same, and a method of manufacturing the rectifying device. The rectifying device includes a pair of electrodes, and a carrier transporter arranged between the pair of electrodes and composed of one or multiple carbon nanotubes. In order that a first interface between one electrode of the pair of electrodes and the carrier transporter and a second interface between the other electrode of the pair of electrodes and the carrier transporter may have different barrier levels, connection configuration of them are made different.

Abstract: Disclosed is a production apparatus of a wired member, including: a mask forming unit that forms a mask on a transfer substrate by using a toner in accordance with an electrophotographic method so as to be transferable to a member to be wired, the mask corresponding to a wiring pattern to be formed on the member to be wired; a mask transferring unit that transfers the mask formed on the transfer substrate by the toner to the member to be wired; a conductive film forming unit that supplies a conductive material onto the mask-transferred side of the member to be wired to form a film of the conductive material thereon; and a mask removing unit that removes the mask from the member to be wired on which the film of the conductive material has been formed.

Abstract: Provided is a nanotube-polymer composite which can effectively utilize characteristics of a carbon nanotube structure. The composite includes a carbon nanotube structure and a polymer, in which: the carbon nanotube structure has a network structure constructed by mutually cross-linking functional groups bonded to multiple carbon nanotubes through chemical bonding of the functional groups together; and the polymer is filled in the network structure.

Abstract: Provided are a carbon nanotube structure more excellent in electric conductivity, thermal conductivity, and mechanical strength, and a method of manufacturing the carbon nanotube structure. A carbon nanotube composite structure is characterized by including: a first carbon nanotube structure in which functional groups bonded to plural carbon nanotubes are chemically bonded and mutually cross-linked to construct a network structure; and a second carbon nanotube structure in which functional groups bonded to plural carbon nanotubes are chemically bonded and mutually cross-linked to construct a network structure, the second carbon nanotube structure being combined with the network structure of the first carbon nanotube structure.

Abstract: Provided is a nanotube-polymer composite which can effectively utilize characteristics of a carbon nanotube structure. The composite includes a carbon nanotube structure and a polymer, in which: the carbon nanotube structure has a network structure constructed by mutually cross-linking functional groups bonded to multiple carbon nanotubes through chemical bonding of the functional groups together; and the polymer is filled in the network structure.

Abstract: Provided is a nanotube-polymer composite which can effectively utilize characteristics of a carbon nanotube structure. The composite includes a carbon nanotube structure and a polymer, in which: the carbon nanotube structure has a network structure constructed by mutually cross-linking functional groups bonded to multiple carbon nanotubes through chemical bonding of the functional groups together; and the polymer is filled in the network structure.

Abstract: An electrical connection structure that is able to electrically connect wiring to a biopolymer, a production method of the electrical connection structure, and an electric wiring method which is able to perform wiring on a nanometer-scale. A first aspect of the production method of the present invention uses a carbon nanotube as an electrode, and makes the carbon nanotube contact the biopolymer. A second aspect of the production method applies electric current between the electrode and the biopolymer of the first aspect. The electrical connection structure of the present invention comprises at least the electrode formed by the carbon nanotube and the biopolymer, wherein the electrode is in contact with the biopolymer. In the electric wiring method of the present invention, the electrode formed by the carbon nanotube contacts the biopolymer to complete an electrical connection.

Abstract: An electrical connection structure that is able to electrically connect wiring to a biopolymer, a production method of the electrical connection structure, and an electric wiring method which is able to perform wiring on a nanometer-scale. A first aspect of the production method of the present invention uses a carbon nanotube as an electrode, and makes the carbon nanotube contact the biopolymer. A second aspect of the production method applies electric current between the electrode and the biopolymer of the first aspect. The electrical connection structure of the present invention comprises at least the electrode formed by the carbon nanotube and the biopolymer, wherein the electrode is in contact with the biopolymer. In the electric wiring method of the present invention, the electrode formed by the carbon nanotube contacts the biopolymer to complete an electrical connection.

Abstract: A method for producing a carbon nanotube thin film comprises a step of dropping a mixed liquid containing carbon nanotubes and an ionic liquid onto a liquid surface of a film forming liquid to spread the carbon nanotubes on the liquid surface.

Abstract: The present invention discloses a method of synthesizing an aliphatic polymer having a ketone group in the main chain thereof, in which polyhydric alcohol (for example, glycerin) as a raw material is polymerized in the presence of a catalyst, and a method of preparing a composition containing an aliphatic polymer having a ketone group in the main chain thereof, including such a process.

Abstract: The present invention provides an electrode for electrochemical measurement including a carbon nanotube, a catalyst causing a specific chemical reaction, and an insulator in which the carbon nanotube and the catalyst are embedded, wherein a part of the catalyst is exposed at the surface of the insulator and a part of the carbon nanotube is exposed at the surface of the insulator to form an electoconductive portion, or wherein a part of the catalyst is exposed at the surface of the insulator, and a part of the carbon nanotube is electrically connected to the exposed catalyst to form an electoconductive portion.

Abstract: Provided are a carbon nanotube structure more excellent in electric conductivity, thermal conductivity, and mechanical strength, and a method of manufacturing the carbon nanotube structure. A carbon nanotube composite structure is characterized by including: a first carbon nanotube structure in which functional groups bonded to plural carbon nanotubes are chemically bonded and mutually cross-linked to construct a network structure; and a second carbon nanotube structure in which functional groups bonded to plural carbon nanotubes are chemically bonded and mutually cross-linked to construct a network structure, the second carbon nanotube structure being combined with the network structure of the first carbon nanotube structure.

Abstract: The present invention provides a structure composed substantially only of carbon nanotubes each having a functional group, the structure being obtained by using a liquid mix characterized by including: the carbon nanotubes; and a crosslinking agent capable of prompting a crosslinking reaction with the functional group. The structure has a network structure in which the carbon nanotubes are surely connected to each other. The present invention also provides a method of forming the structure.

Abstract: The invention provides an aliphatic polymer having a ketone group and ether bonding in its main chain, characterized by comprising structural units represented by the Formula (1) and by the Formula (2). In the Formulae (1) and (2), Ra and Rb each independently represents a substituted or unsubstituted divalent aliphatic hydrocarbon group. Rc represents a substituted or unsubstituted divalent aliphatic hydrocarbon group having ether bonding in a terminal thereof, or a single bond. N1 represents an integer of 1 or more. N2 represents an integer of 0 or more. And, n1+n2 is in a range of 2 to 1000. The polymer preferably contains ether bonds and ketone groups in a ratio of 0.01 to 100. The polymer can be substantially comprised of a structural unit represented by the Formula (1) as a repeating unit. A resin composition containing as a component structural units represented by the Formula (1) is also provided. The resin composition may further comprise an electrically conductive powder.

Abstract: Disclosed is a production apparatus of a wired member, including: a mask forming unit that forms a mask on a transfer substrate by using a toner in accordance with an electrophotographic method so as to be transferable to a member to be wired, the mask corresponding to a wiring pattern to be formed on the member to be wired; a mask transferring unit that transfers the mask formed on the transfer substrate by the toner to the member to be wired; a conductive film forming unit that supplies a conductive material onto the mask-transferred side of the member to be wired to form a film of the conductive material thereon; and a mask removing unit that removes the mask from the member to be wired on which the film of the conductive material has been formed.

Abstract: The present invention provides an electrode for electrochemical measurement including: a carbon nanotube and an insulator that encloses carbon nanotube, wherein: the carbon nanotube is enclosed by being chemically bonded with the insulator; and part of the carbon nanotube forms an electrical conduction part exposed at a surface of the insulator. The carbon nanotube can include plural carbon nanotubes electrically connected with each other. The electrical conduction part can be part of the plural carbon nanotubes exposed in plural spots at a surface of the insulator through the insulator. The plural carbon nanotubes can form a network structure by being electrically connected with each other by chemical bonding. The present invention also provides a method for manufacturing the electrode for electrochemical measurement.

Abstract: To provide a carbon nanotube device capable of efficiently exerting various electrical or physical characteristics of a carbon nanotube, the present invention provides: a carbon nanotube device, in which a carbon nanotube structure layer having a network structure in which plural carbon nanotubes mutually cross-link, is formed in an arbitrary pattern on a surface of a base body; and a method of manufacturing the carbon nanotube device with which the carbon nanotube can be suitably manufactured.

Abstract: The present invention provides an organic conductor comprising a deoxyribonucleic acid (DNA) and an electric charge-donating material bonded to the deoxyribonucleic acid, and an organic conductor comprising at least two DNAs; and an electric charge-transfer substance bonding to each base of the two DNAs.

Abstract: A carbon nanotube dispersion includes a carbon nanotube compound represented by structural formula A and a dispersion medium in which the carbon nanotube is dispersed or dissolved, wherein a moiety represented by double lines represents a carbon nanotube R1 represents a hydrogen atom, a substituted or unsubstituted alkyl group having one or two carbon atoms, a substituted or unsubstituted aryl group or a substituted or unsubstituted carbodiimide group, R2 represents a substituted or unsubstituted alkyl group having from 1 to 4 carbon atoms, and m and n each independently represents an integer of 1 or more.

Abstract: A method of producing an organic-inorganic composite insulating material for electronic element comprises subjecting a mixture of an organic polymer or its solution and a metal alkoxide or its solution as a starting material to sol-gel reaction of the metal alkoxide in the presence of the organic polymer.