A method of manufacturing a display device in a chamber in which a material including yttrium is coated on an inner surface includes: forming a first layer pattern by dry etching on a substrate; depositing a second layer material on the first layer pattern; forming a photoresist pattern on the second layer material; completing a second layer pattern by using the photoresist pattern as an etch mask; and performing an additional acid etching process by using an etching solution including at least one of hydrochloric acid, sulfuric acid, or nitric acid before the forming of the photoresist pattern on the second layer material after the dry etching to form the first layer pattern.

This wet etching method comprises rotating a substrate (W), supplying an etching chemical to a first surface (a surface for forming a device) of the rotating substrate, and supplying an etching inhibitor (DIW) to a second surface (a surface which is not used for forming a device) during the supplying the etching chemical to the substrate. The etching inhibitor moves past an edge (WE) of the substrate to swirl onto the first surface and reaches a first region extending from the edge of the substrate on the periphery of the first surface to a first radial position located radially inward from the edge on the first surface. Thus, it is possible to perform an excellent bevel etching treatment on the upper layer of the substrate having a two-layered film formed thereon.

Disclosed is a turntable cloth peeling jig including: a cylindrical winding cylinder including a slit formed on an outer periphery of the cylindrical winding cylinder and extending in an axial direction thereof; a cloth clamping member disposed inside the winding cylinder and configured to clamp an outer peripheral edge of a cloth inserted into the slit; an extension bar attached to one end portion of the winding cylinder so as to extend coaxially therewith; an engaging portion provided at a tip end portion of the extension bar and engaged with a rotation jig configured to rotate the winding cylinder; and a handle provided in the engaging portion and configured to support the winding cylinder when rotating the rotating jig.

A substrate processing apparatus includes a substrate holder, and a discharge head for peripheral area from which a fluid is discharge toward a surface peripheral area of the substrate held on the substrate holder. The discharge head for peripheral area includes multiple nozzles, and a support part that supports the nozzles integrally. The nozzles include a processing liquid nozzle from which a processing liquid is discharged toward the surface peripheral area, and a gas nozzle from which gas is discharged toward the surface peripheral area. The gas nozzle is placed upstream of a rotative direction of the substrate relative to the processing liquid nozzle.

In some examples, a device comprises a wafer chuck, a member having a surface facing the wafer chuck, a blade supported by the surface, a first vacuum nozzle extending through the member and having a first vacuum orifice facing a same direction as the surface, and a second vacuum nozzle extending through the member and having a second vacuum orifice facing the same direction as the surface. The first and second vacuum orifices are on opposing sides of the blade.

A substrate treatment method for treating a substrate, includes the steps of: (A) heating the substrate having a coating film formed on a surface thereof by supply of a coating solution; (B), after the (A) step, moving a discharge destination of a removing solution from a peripheral position on the surface of the substrate toward a center side of the substrate and turning it back at a first position to return it again to the peripheral position while rotating the substrate; (C), after the (B) step, moving the discharge destination of the removing solution from the peripheral position on the surface of the substrate toward center side of the substrate and turning it back at a second position closer to an outside than the first position to return it again to the peripheral position while rotating the substrate; and (D), after the (C) step, heating again the substrate.

A substrate processing method includes: a first etching step of performing a first etching by supplying an etching liquid on a front surface of a substrate while rotating the substrate, wherein the first etching is performed under a condition in which a second etching amount of an etching target film in a second region on a peripheral edge of the front surface, is greater than a first etching amount of the etching target film in a first region on a center side of the front surface; and a second etching step of performing a second etching by supplying the etching liquid to the front surface of the substrate while rotating the substrate, wherein the second etching is performed under a condition in which the second etching amount of the etching target film in the second region of the front surface of the substrate is smaller than the first etching amount of the etching target film in the first region.

A wafer cleaning apparatus includes a polishing unit used in chemical mechanical polishing (CMP) of a wafer and a cleaning dispensing unit arranged to direct cleaning fluids toward a far edge of the wafer after the CMP of the wafer. A wafer cleaning method includes CMP of a wafer by a polishing unit and directing cleaning fluids toward a far edge of the wafer after the CMP of the wafer by a cleaning dispensing unit. Another method can include CMP, applying deionized water, and applying pH adjuster having a pH range from about 2 to about 13.

A plasma processing apparatus for cleaning a peripheral portion of a substrate by plasma and comprising a depressurizable processing container accommodating a substrate is disclosed. The processing container includes a substrate support for supporting a substrate and including a central electrode facing a central portion of the supported substrate supported by the substrate support; a lower ring electrode formed in a ring shape to face a lower surface of a peripheral portion of the substrate supported by the substrate support; and an upper ring electrode disposed to face an upper surface of the peripheral portion of the substrate supported by the substrate support. The central electrode is grounded, a radio frequency (RF) power is supplied to each of the upper and lower ring electrodes, and the RF power is supplied to at least one of the upper and lower ring electrodes via a phase adjuster configured to adjust the phase of the RF power.

Provided are a wafer cleaning apparatus based on light irradiation capable of effectively cleaning residue on a wafer without damaging the wafer, and a wafer cleaning system including the cleaning apparatus. The wafer cleaning apparatus is configured to clean residue on the wafer by light irradiation and includes: a light irradiation unit configured to irradiate light onto the wafer during the light irradiation; a wafer processing unit configured accommodate the wafer and to control a position of the wafer such that the light is irradiated onto the wafer during the light irradiation; and a cooling unit configured to cool the wafer after the light irradiation has been completed. The light irradiation unit, the wafer processing unit, and the cooling unit are sequentially arranged in a vertical structure with the light irradiation unit above the wafer processing unit and the wafer processing unit above the cooling unit.