Abstract: There is provided an etching method which includes: supplying an etching gas to a workpiece including a first SiGe-based material and a second SiGe-based material having different Ge concentrations; and selectively etching the first SiGe-based material and the second SiGe-based material with respect to the other using a difference in incubation time until the first SiGe-based material and the second SiGe-based material begin to be etched by the etching gas.

Abstract: An etching method includes etching a silicon-containing film formed on a surface of a substrate by supplying an iodine heptafluoride gas and a basic gas to the substrate.

Abstract: There is provided an etching method which includes: forming a blocking film configured to prevent an etching gas for etching a silicon-containing film from passing through each pore of a porous film and prevent the etching gas from being supplied to a film not to be etched, by supplying at least one film-forming gas to a substrate in which the silicon-containing film, the porous film, and the film not to be etched are sequentially formed adjacent to each other in a lateral direction; and etching the silicon-containing film by supplying the etching gas.

Abstract: In the present disclosure, the high-pressure chamber includes a chamber main body including a flat rectangular parallelepiped block of a metal which is formed with a flat cavity that serves as a substrate processing space in which a processing using a high-pressure fluid is performed on a substrate, and the substrate processing space being formed by machining the block from one of faces of the block other than the widest face towards another face opposing thereto. In a case where the cavity is constituted as a through hole, the though hole is provided with a cover configured to open or close the cavity on one side of the through hole, and a second block configured to air-tightly seal the cavity on the other side.

Abstract: A substrate processing method and apparatus which can remove an anti-drying liquid, which has entered a three-dimensional pattern with recessed portions formed in a substrate, in a relatively short time. The substrate processing method includes the steps of: carrying a substrate, having a three-dimensional pattern formed in a surface, into a processing container, said pattern being covered with an anti-drying liquid that has entered the recessed portions of the pattern; heating the substrate and supplying a pressurizing gas or a fluid in a high-pressure state into the processing container, thereby forming a high-pressure atmosphere in the processing container before the anti-drying liquid vaporizes to such an extent as to cause pattern collapse and bringing the anti-drying liquid into a high-pressure state while keeping the liquid in the recessed portions of the pattern; and thereafter discharging a fluid in a high-pressure state or a gaseous state from the processing container.

Abstract: A substrate processing method includes supplying onto a substrate a processing liquid which contains a volatile component and forms a film, vaporizing the volatile component in the processing liquid such that the processing liquid solidifies or cures on the substrate and forms a film on the substrate, and supplying onto the film formed on the substrate a removing liquid which removes the processing liquid. The processing liquid is supplied onto the substrate after dry etching or ashing is applied to the substrate.

Abstract: Disclosed is a separation and regeneration apparatus including: a supercritical processing unit configured to generate a mixed gas including a first fluorine-containing organic solvent having a first boiling point and a second fluorine-containing organic solvent having a second boiling point lower than the first boiling point; and a distillation tank configured to store hot water having a temperature between the first boiling point and the second boiling point, in which the mixed gas is input into the hot water to be separated into the first fluorine-containing organic solvent in a liquid state and the second fluorine-containing organic solvent in a gas state, in which an introduction line configured to guide the mixed gas from the supercritical processing unit to the distillation tank is provided and a distal end of the introduction line is disposed in the hot water.

Abstract: A substrate processing method and apparatus for preventing evaporation of an anti-drying fluorine-containing organic solvent from a substrate during transportation of the substrate into a processing container and can prevent decomposition of a fluorine-containing organic solvent in the processing container. A substrate, the surface of which is covered with a first fluorine-containing organic solvent, is carried into a processing container. The first fluorine-containing organic solvent is removed from the substrate surface by forming a high-pressure fluid atmosphere of a mixture of the first fluorine-containing organic solvent and a second fluorine-containing organic solvent, having a lower boiling point than the first fluorine-containing organic solvent, in the processing container e.g. by supplying a high-pressure fluid of the second fluorine-containing organic solvent into the processing container.

Abstract: Productivity can be improved. A substrate processing method includes a processing liquid supplying process of supplying a processing liquid, which contains a volatile component and forms a film on a substrate, onto the substrate on which a pre-treatment, which requires atmosphere management or time management after the pre-treatment, is performed; and an accommodating process of accommodating, in a transfer container, the substrate on which the processing liquid is solidified or cured by volatilization of the volatile component.

Abstract: The present disclosure provides a substrate processing apparatus including: a processing chamber configured to process a substrate; a fluid supply source configured to supply a substrate processing fluid used in processing for the substrate in a predetermined pressure; a constant pressure supplying path configured to supply the substrate processing fluid from the fluid supply source to the processing chamber in a predetermined pressure without boosting the pressure of the substrate processing liquid; a boosted pressure supplying path configured to boost the pressure of the substrate processing fluid from the fluid supply source into a predetermined pressure by a booster mechanism and supply the pressure boosted substrate processing fluid to the processing chamber; and a control unit configured to switch over the constant pressure supplying path and the boosted pressure supplying path.

Abstract: A method for cleaning a substrate, includes supplying to a substrate having a hydrophilic surface a film-forming processing liquid which includes a volatile component and forms a film on the substrate, vaporizing the volatile component in the film-forming processing liquid such that the film-forming processing liquid solidifies or cures on the substrate and forms a processing film on the hydrophilic surface of the substrate, and supplying to the substrate having the processing film a strip-processing liquid for stripping the processing film from the substrate.

Abstract: In an etching method for removing a processing target layer formed on a substrate for manufacturing electronic devices, a first break-through process of removing an oxide film formed on a surface of the processing target layer is performed, and a first main etching process of etching the processing target layer is performed after the first break-through process. Then, a second break-through process of removing the oxide film exposed after the first main etching process is performed, and a second main etching process of etching the processing target layer is performed after the second break-through process.

Abstract: A method for cleaning a substrate includes supplying to a substrate a film-forming processing liquid which includes a volatile component and forms a film on the substrate, vaporizing the volatile component in the film-forming processing liquid such that the film-forming processing liquid solidifies or cures on the substrate and forms a processing film on the substrate, supplying to the substrate having the processing film a strip-processing liquid which strips the processing film from the substrate, and supplying to the processing film formed on the substrate a dissolving-processing liquid which dissolves the processing film after the supplying of the strip-processing liquid.

Abstract: Disclosed is a substrate liquid processing apparatus. The substrate liquid processing apparatus includes a processing unit, a nozzle, a silylation liquid supply mechanism, and a blocking fluid supply mechanism. The processing unit performs a water repellency imparting processing on a substrate by supplying a silylation liquid to the substrate. The nozzle includes an ejection port configured to supply the silylation liquid to the substrate positioned in the processing unit, and a silylation liquid flow path in which the silylation liquid flows toward the ejection port. The silylation liquid supply mechanism supplies the silylation liquid to the silylation liquid flow path in the nozzle through a silylation liquid supply line. The blocking fluid supply mechanism supplies a blocking fluid that blocks the silylation liquid within the silylation liquid flow path in the nozzle from an atmosphere outside the ejection port.

Abstract: Disclosed is a substrate processing method. The method includes: supplying a rinse liquid, IPA, a first fluorine-containing organic solvent, a second fluorine-containing organic solvent to a wafer within an outer chamber of a liquid processing unit; conveying the wafer to a supercritical processing unit container; and supplying a supercritical processing fluorine-containing organic solvent in a supercritical high-pressure fluid state to the wafer within the supercritical processing unit container. At least during the supply of the IPA, a low-humidity N2 gas is supplied into the outer chamber so that the inside of the outer chamber is formed as a low-humidity N2 gas atmosphere, and thus moisture absorption into the IPA is prevented.

Abstract: The present disclosure provides a substrate processing apparatus including: a processing chamber configured to process a substrate; a fluid supply source configured to supply a substrate processing fluid used in processing for the substrate in a predetermined pressure; a constant pressure supplying path configured to supply the substrate processing fluid from the fluid supply source to the processing chamber in a predetermined pressure without boosting the pressure of the substrate processing liquid; a boosted pressure supplying path configured to boost the pressure of the substrate processing fluid from the fluid supply source into a predetermined pressure by a booster mechanism and supply the pressure boosted substrate processing fluid to the processing chamber; and a control unit configured to switch over the constant pressure supplying path and the boosted pressure supplying path.

Abstract: A substrate cleaning system has a first processing apparatus including a first holding device for holding a substrate, and a treatment solution supply device for supplying onto the entire portion of the front surface of the substrate a treatment solution which includes a volatile component and solidifies or is cured to form a treatment film, and a second processing apparatus including a second holding device for holding the substrate, and a removal-solution supply device for supplying onto the substrate a removal solution which removes the treatment film formed on the front surface of the substrate after the treatment solution supplied by the treatment solution supply device solidifies or is cured.

Abstract: The present disclosure provides a substrate processing apparatus including: a processing chamber configured to process a substrate; a fluid supply source configured to supply a substrate processing fluid used in processing for the substrate in a predetermined pressure; a constant pressure supplying path configured to supply the substrate processing fluid from the fluid supply source to the processing chamber in a predetermined pressure without boosting the pressure of the substrate processing liquid; a boosted pressure supplying path configured to boost the pressure of the substrate processing fluid from the fluid supply source into a predetermined pressure by a booster mechanism and supply the pressure boosted substrate processing fluid to the processing chamber; and a control unit configured to switch over the constant pressure supplying path and the boosted pressure supplying path.

Abstract: A supercritical drying method for a semiconductor substrate is disclosed. The method may include introducing the semiconductor substrate into a chamber in a state, a surface of the semiconductor substrate being wet with alcohol, substituting the alcohol on the semiconductor substrate with a supercritical fluid of carbon dioxide by impregnating the semiconductor substrate to the supercritical fluid in the chamber, and discharging the supercritical fluid and the alcohol from the chamber and reducing a pressure inside the chamber. The method may also include performing a baking treatment by supplying an oxygen gas or an ozone gas to the chamber after the reduction of the pressure inside the chamber.

Abstract: A method for cleaning a substrate includes supplying a treatment solution which includes a volatile component onto the front surface of a substrate, solidifying or curing the treatment solution through vaporization of the volatile component of the treatment solution such that a treatment film is formed on the entire portion of the front surface of the substrate, treating a different surface of the substrate while the entire portion of the front surface of the substrate is covered with the treatment film, and supplying to the substrate a removal solution which removes the treatment film in the amount sufficient such that the treatment film covering the entire portion of the front surface of the substrate is removed substantially in entirety after the treating of the different surface of the substrate is finished.