A method for washing an aluminum nitride single crystal substrate, the aluminum nitride single crystal substrate including: an aluminum-polar face; and a nitrogen-polar face opposite to the aluminum-polar face, the method including: (a) scrubbing a surface of the nitrogen-polar face.

A cleaning system includes at least one cleaning module configured to receive a substrate after a chemical mechanical polishing (CMP) process and to remove contaminants on the substrate using a cleaning solution. The cleaning system further includes a cleaning solution supply system configured to supply the cleaning solution to the at least one cleaning module. The cleaning solution supply system includes at least one temperature control system. The at least one temperature control system includes a heating device configured to heat the cleaning solution, a cooling device configured to cool the cleaning solution, a temperature sensor configured to monitor a temperature of the cleaning solution, and a temperature controller configured to control the heating device and the cooling device.

There is provided a drying apparatus for covering an upper surface of the substrate with an uneven pattern formed thereon with a liquid film and subsequently drying the substrate, including: a first heat transfer part whose temperature is adjusted to a first temperature, wherein a first heat is transferred between the first heat transfer part and the substrate by a first temperature difference; a second heat transfer part whose temperature is adjusted to a second temperature different from the first temperature, wherein a second heat is transferred between the second heat transfer part and the substrate by a second temperature difference; and a controller configured to control the first temperature and the second temperature and to control a surface tension distribution of the liquid film so as to control an agglomeration of the liquid film.

When performing a liquid processing on a substrate W being rotated and removing a processing liquid by a cleaning liquid, a cleaning liquid nozzle 421 configured to discharge a cleaning liquid slantly with respect to a surface of the substrate W toward a downstream side of a rotational direction of the substrate W and a gas nozzle 411 configured to discharge a gas toward a position adjacent to a central portion side of the substrate W when viewed from a liquid arrival position R of the cleaning liquid are moved from the central portion side toward a peripheral portion side. A rotation number of the substrate is varied such that rotation number in a period during which the liquid arrival position R moves in the second region becomes smaller than a maximum rotation number in a period during which the liquid arrival position moves in the first region.

A low surface tension liquid supply unit supplies a low surface tension liquid onto the upper surface of a substrate to form a liquid film of the low surface tension liquid on the substrate. An opening is formed in a central region of the liquid film of an organic solvent. The liquid film is removed from the upper surface of the substrate by expanding the opening. While a low surface tension liquid is supplied from the low surface tension liquid supply unit, to the liquid film, toward a liquid landing point set outside the opening, the liquid landing point is moved so as to follow the expansion of the opening. While an facing surface of a drying head faces a dry region set inside the opening to form a low-humidity space between the facing surface and the dry region, with the low-humidity space having a humidity lower than that outside the space, the dry region and the facing surface are moved so as to follow the expansion of the opening.

A substrate cleaning method according to an aspect of the present disclosure includes: supplying a film-forming treatment liquid containing a volatile component to a substrate to form a film on the substrate; supplying a peeling treatment liquid, which peels off a treatment film from the substrate, to the treatment film formed by solidifying or curing the film-forming treatment liquid on the substrate due to volatilization of the volatile component; and supplying a hydrophobic liquid, which hydrophobizes the substrate, to the substrate to which the peeling treatment liquid has been supplied.

A method of cleaning and polishing a backside surface of a semiconductor wafer is provided. The method includes placing an abrasive brush, comprising an abrasive tape wound around an outer surface of a brush member of the abrasive brush, on the backside surface of the semiconductor wafer. The method also includes rotating the brush member to polish the backside surface of the semiconductor wafer by abrasive grains formed on the abrasive tape and to clean the backside surface of the semiconductor wafer by the brush member which is not covered by the abrasive tape.

A method for cleaning a semiconductor wafer to clean a semiconductor wafer after polishing, including: performing a first ozone-water treatment step of cleaning the polished semiconductor wafer with ozone water to form an oxide film; performing a brush cleaning step of brush-cleaning the semiconductor wafer with carbonated water after the first ozone-water treatment step; and then performing a second ozone-water treatment step including cleaning the semiconductor wafer with hydrofluoric acid to remove the oxide film, followed by cleaning with ozone water to form an oxide film again. This second ozone-water treatment step is performed one or more times. The method for cleaning a semiconductor wafer achieves cleaning level equivalent to that with SC1, reduces or prevents defect generation on a wafer surface and surface roughness degradation which would otherwise occur when SC1 is used, and also results in cost reduction and environmental load reduction.

A substrate processing apparatus includes a substrate holding device, a rotation mechanism, a drying liquid supply nozzle, a movement mechanism, a flow rate control mechanism, and a control device including circuitry which controls one or more of the rotation mechanism, movement mechanism and flow rate control mechanism such that the drying liquid forms a drying liquid flow line having distance (L) equal to or less than preset upper limit distance (M), where when a liquid contact point is position at which the drying liquid discharged from the nozzle reaches the substrate, the flow line is formed when the liquid contact point is moved from a center portion of the substrate toward a peripheral edge portion of the substrate, and the distance (L) of the flow line is measured from center of the liquid contact point to an edge of the flow line on a rotation center side of the substrate.

A method for in-situ dry cleaning of a SiGe semiconductor surface doses the SiGe surface with ex-situ wet HF in a clean ambient environment or in-situ dosing with gaseous NH.sub.4F to remove oxygen containing contaminants. Dosing the SiGe surface with atomic H removes carbon containing contaminants. Low temperature annealing pulls the surface flat. Passivating the SiGe semiconductor surface with H.sub.2O.sub.2 vapor for a sufficient time and concentration forms an a oxygen monolayer(s) of —OH sites on the SiGe. Second annealing the SiGe semiconductor surface is conducted at a temperature below that which would induce dopant diffusion. A method for in-situ dry cleaning of a SiGe semiconductor surface, ex-situ degreases the Ge containing semiconductor surface and removes organic contaminants. The surface is then dosed with HF(aq) or NH4F(g) generated via NH.sub.3+NH or NF.sub.3 with H.sub.2 or H.sub.2O to remove oxygen containing contaminants. In-situ dosing of the SiGe surface with atomic H removes carbon containing contaminants.