Abstract: A carbon-silicon composite material is suitable to be used as a negative electrode material for battery. It is a carbon-silicon composite material having such a structure that a silicon particle exists in a resin thermolysis product, wherein, in a case where the carbon-silicon composite material is dipped into an electrolytic solution ((ethylene carbonate/diethyl carbonate (1/1 (volume ratio))) under the conditions of 760 mmHg, 30° C., and 60 min., liquid adsorption of the electrolytic solution per the carbon-silicon composite material of 1 g is 0.65-1.5 mL.

Abstract: The present invention provides a carbon-silicon composite material suitable (e.g., high capacity; small irreversible capacity; long cycle life) to be used as a negative electrode material for battery. The carbon-silicon composite material comprises a carbon black and a silicon particle, wherein the carbon black and the silicon particle are bound via a resin thermolysis product.

Abstract: A substrate processing method of processing a substrate using a block copolymer containing a hydrophilic polymer and a hydrophobic polymer, the substrate processing method includes: a block copolymer coating step of applying the block copolymer onto the substrate on which a predetermined projecting and recessed pattern is formed, to form a coating film of the block copolymer; a polymer separation step of phase-separating the block copolymer into the hydrophilic polymer and the hydrophobic polymer; a polymer removal step of selectively removing the hydrophilic polymer from the phase-separated block copolymer; and after the block copolymer coating step and before the polymer removal step, a film thickness reduction step of reducing a film thickness of the coating film of the block copolymer.

Abstract: A water-absorbing resin composition including 100 parts by weight of water-absorbing resin particles and 0.01 to 1 part by weight of additive particles, wherein a percent by weight of the additive particles, (x [%]), based on 100% by weight of the water-absorbing resin particles in the composition, and weight ratio of free additive particles, (y), relative to the percent by weight, (x [%]), satisfy the following formula: 0.04(x)0.1?y?0.2(x)0.5.

Abstract: To provide a carbon fiber having low contact resistance and high conductivity. To provide a carbon fiber that satisfies the following Requirements. A diameter of the carbon fiber is 0.5-6.5 ?m. A length of the carbon fiber is 5-65 ?m. The carbon fiber has “waviness”. The carbon fiber has protruding portions. A protruding height of the protruding portions is 20-300 nm. The number of protruding portions is 3-25 per 1 ?m length (a length along the carbon fiber) of the carbon fiber. The carbon fiber contains carbon black. A primary particle diameter of the carbon black is 21-69 nm.

Abstract: A substrate treatment method using a block copolymer containing a hydrophilic polymer and a hydrophobic polymer includes a polymer separating step, wherein a ratio of a molecular weight of the hydrophilic polymer in the block copolymer is adjusted to 20% to 40% so that the hydrophilic polymers align at positions corresponding to a hexagonal close-packed structure in a plan view after the polymer separating step, and at the polymer separating step, a columnar first hydrophilic polymer is phase-separated on each of circular patterns of hydrophobic coating films and a columnar second hydrophilic polymer is phase-separated between the first hydrophilic polymers, and a diameter of the circular pattern is set so that the first hydrophilic polymers and the second hydrophilic polymers align at positions corresponding to the hexagonal close-packed structure in a plan view.

Abstract: The present invention, when forming a pattern on a substrate, forms a film of a block copolymer containing at least two polymers on the substrate, heats the film of the block copolymer under a solvent vapor atmosphere to subject the block copolymer to phase separation, and removes one of the polymers in the film of the phase-separated block copolymer, thereby accelerating fluidization of the polymers of the block copolymer to enable acceleration of the phase separation.

Abstract: The present invention, when forming a pattern on a substrate, forms a film of a block copolymer containing at least two polymers on the substrate, heats the film of the block copolymer under a solvent vapor atmosphere to subject the block copolymer to phase separation, and removes one of the polymers in the film of the phase-separated block copolymer, thereby accelerating fluidization of the polymers of the block copolymer to enable acceleration of the phase separation.

Abstract: A substrate treatment method includes: a polymer separation step of phase-separating a block copolymer into a hydrophilic polymer and a hydrophobic polymer; and a polymer removal step of selectively removing the hydrophilic polymer from the phase-separated block copolymer, wherein in the polymer removal step, the hydrophilic polymer is removed by: irradiating the phase-separated block copolymer with an energy ray; then supplying a first polar organic solvent having a first degree of dissolving the hydrophilic polymer, being lower in boiling point than water and capable of dissolving water, and not dissolving the hydrophobic polymer, to the block copolymer; and then supplying a second polar organic solvent having a second dissolving degree lower than the first dissolving degree, being higher in boiling point than water, and not dissolving the hydrophobic polymer, to the block copolymer.

Abstract: A substrate treatment method of treating a substrate using a block copolymer containing a hydrophilic polymer and a hydrophobic polymer, includes: a resist pattern formation step of forming a predetermined resist pattern by a resist film on the substrate; a thin film formation step of forming a thin film for suppressing deformation of the resist pattern on a surface of the resist pattern; a block copolymer coating step of applying a block copolymer to the substrate after the formation of the thin film; and a polymer separation step of phase-separating the block copolymer into the hydrophilic polymer and the hydrophobic polymer.

Abstract: Disclosed is a coating apparatus capable of enhancing the film thickness uniformity. The coating apparatus includes a nozzle and a moving mechanism. The nozzle includes a storage chamber that stores a coating liquid and a slit-like flow path that is in communication with the storage chamber, and discharges the coating liquid through a discharge port formed at a front end of the flow path. The moving mechanism moves the nozzle and the substrate relatively to each other along a surface of the substrate. Also, in the flow path provided in the nozzle, flow resistance at the central portion in the longitudinal direction is larger than that at both end portions in the longitudinal direction.

Abstract: The present invention is configured to: form, on a substrate, a neutral layer having an intermediate affinity to a hydrophilic polymer and a hydrophobic polymer; form a resist pattern by performing exposure processing on a resist film formed on the neutral layer and then developing the resist film after the exposure processing; perform a surface treatment on the resist pattern by supplying an organic solvent having a polarity to the resist pattern; apply the block copolymer onto the neutral layer; and phase-separate the block copolymer on the neutral layer into the hydrophilic polymer and the hydrophobic polymer.

Abstract: A substrate treatment method includes: forming a plurality of circular patterns of a resist film on a substrate; thereafter applying a first block copolymer; then phase-separating the first block copolymer into a hydrophilic polymer and a hydrophobic polymer; thereafter selectively removing the hydrophilic polymer; then selectively removing the resist film from a top of the substrate; thereafter applying a second block copolymer to the substrate; then phase-separating the second block copolymer into a hydrophilic polymer and a hydrophobic polymer; and thereafter selectively removing the hydrophilic polymer from the phase-separated second block copolymer. A ratio of a molecular weight of the hydrophilic polymer in the first block copolymer and the second block copolymer is 20% to 40%.

Abstract: A disclosed substrate cleaning apparatus for cleaning a back surface of a substrate includes a first substrate supporting portion configured to support the substrate at a first area of a back surface of the substrate, the back surface facing down; a second substrate supporting portion configured to support the substrate at a second area of the back surface of the substrate, the second area being separated from the first area; a cleaning liquid supplying portion configured to supply cleaning liquid to the back surface of the substrate; a drying portion configured to dry the second area of the back surface of the substrate; and a cleaning portion configured to clean a third area of the back surface of the substrate when the substrate is supported by the first substrate supporting portion, the third area including the second area, and a fourth area of the back surface of the substrate when the substrate is supported by the second substrate supporting portion, the fourth area excluding the second area of the back

Abstract: A substrate treatment method includes: forming a plurality of circular patterns of a resist film on a substrate; thereafter applying a first block copolymer; then phase-separating the first block copolymer into a hydrophilic polymer and a hydrophobic polymer; thereafter selectively removing the hydrophilic polymer; then selectively removing the resist film from a top of the substrate; thereafter applying a second block copolymer to the substrate; then phase-separating the second block copolymer into a hydrophilic polymer and a hydrophobic polymer; and thereafter selectively removing the hydrophilic polymer from the phase-separated second block copolymer. A ratio of a molecular weight of the hydrophilic polymer in the first block copolymer and the second block copolymer is 20% to 40%.

Abstract: The present invention is a pattern forming method of forming a pattern on a substrate using a block copolymer, the pattern forming method including the steps of: forming a film of a block copolymer containing at least two kinds of polymers on the substrate; heating the film of the block copolymer; irradiating the heated film of the block copolymer with ultraviolet light in an atmosphere of an inert gas; and supplying an organic solvent to the film of the block copolymer irradiated with the ultraviolet light.

Abstract: A photovoltaic system includes a pole member which stands on an installation surface, a connecting support member disposed on an upper end section of the pole member, a rail member supported by the connecting support member, and a photovoltaic cell module disposed on the rail member, wherein the pole supporting member includes a lower section that covers at least a portion of an outer peripheral surface of the upper end section of the pole member.

Abstract: A photoresist pattern used for forming a pattern of a block copolymer is formed on a substrate, and then an acid solution is supplied and an alkaline solution is further supplied to the photoresist pattern so as to slim and smooth the photoresist pattern. A block copolymer solution is applied to the substrate on which the smoothed photoresist pattern has been formed, to form a film of the block copolymer, and the film is heated.

Abstract: A disclosed substrate cleaning apparatus for cleaning a back surface of a substrate includes a first substrate supporting portion configured to support the substrate at a first area of a back surface of the substrate, the back surface facing down; a second substrate supporting portion configured to support the substrate at a second area of the back surface of the substrate, the second area being separated from the first area; a cleaning liquid supplying portion configured to supply cleaning liquid to the back surface of the substrate; a drying portion configured to dry the second area of the back surface of the substrate; and a cleaning portion configured to clean a third area of the back surface of the substrate when the substrate is supported by the first substrate supporting portion, the third area including the second area, and a fourth area of the back surface of the substrate when the substrate is supported by the second substrate supporting portion, the fourth area excluding the second area of the back

Abstract: The present invention, when forming a pattern on a substrate, forms a film of a block copolymer containing at least two polymers on the substrate, heats the film of the block copolymer under a solvent vapor atmosphere to subject the block copolymer to phase separation, and removes one of the polymers in the film of the phase-separated block copolymer, thereby accelerating fluidization of the polymers of the block copolymer to enable acceleration of the phase separation.