This disclosure relates to a cleaning composition that contains 1) at least one redox agent; 2) at least one alkylsulfonic acid or a salt thereof, the alkylsulfonic acid containing an alkyl group substituted by OH or NH.sub.2; and 3) at least one aminoalcohol.

A substrate processing method includes: holding a substrate having a processing target surface and an opposite surface which is opposite to the processing target surface; preheating a center portion of the opposite surface of the substrate; after the preheating, ejecting a sulfuric acid hydrogen peroxide mixture (SPM) to a peripheral edge portion of the processing target surface of the substrate; and after the ejecting, moving an ejection position of the SPM from the peripheral edge portion of the processing target surface to a center portion of the substrate.

A semiconductor substrate manufacturing method according to an embodiment comprises the steps of: contaminating at least one of a surface layer of a doped semiconductor substrate having a specific resistance of less than 0.1 .Math.cm and a bulk layer below the surface layer with at least one metal of Fe, Cu, and Ni; performing dry oxidation at 950 C. for 30 minutes to forcibly form an oxide film on the surface of the semiconductor substrate; and assessing at least one of the presence and the degree of contamination of metal contained in at least one of the oxide film-formed surface layer and bulk layer by using a photoluminescence assessment method.

This disclosure relates to a cleaning composition that contains 1) at least one redox agent; 2) at least one alkylsulfonic acid or a salt thereof, the alkylsulfonic acid containing an alkyl group substituted by OH or NH.sub.2; 3) at least one aminoalcohol; 4) at least one corrosion inhibitor; 5) at least one water soluble organic solvent; 6) water; and 7) optionally, at least one pH adjusting agent.

Disclosed herein are systems and methods for treating the surface of a microelectronic substrate, and in particular, relate to an apparatus and method for scanning the microelectronic substrate through a cryogenic fluid mixture used to treat an exposed surface of the microelectronic substrate. The fluid mixture may be expanded through a nozzle to form an aerosol spray or gas cluster jet (GCJ) spray may impinge the microelectronic substrate and remove particles from the microelectronic substrate's surface. In one embodiment, the fluid mixture may be maintained to prevent liquid formation within the fluid mixture prior to passing the fluid mixture through the nozzle. The fluid mixture may include nitrogen, argon, helium, neon, xenon, krypton, carbon dioxide, or any combination thereof.

According to one aspect of the present disclosure, there is provided a cleaning method including: cleaning a component in which a deposit adhering to the component constituting an apparatus is removed by supplying and discharging a cleaning gas, wherein the act of cleaning includes controlling the apparatus so that a signal, which indicates a concentration of a predetermined gas generated by a reaction of the deposit and the cleaning gas, reaches a predetermined upper limit value or less and then stays within a range between the predetermined upper limit value and a predetermined lower limit value for a predetermined time period.

The present invention relates to the controlling of the deposition quality of an epitaxial layer, for example of gallium nitride, on a growth plate, for example of silicon, in particular at the level of the edges of the plate. The invention aims, in particular, to reduce the complexity and the production cost of known solutions. The production method according to the invention highlights the existence of a chamfer on each growth plate and provides a self-positioned deposition of a protective film on at least one part of the chamfer using a mechanical mask, preventing the deposition of the protective film on the useful zone Zu through epitaxy.

A method of making a device substrate article having a device modified substrate supported on a glass carrier substrate, including: treating at least a portion of the first surface of a device substrate, at least a portion of a first surface of a glass carrier, or a combination thereof, wherein the treating produces a surface having: silicon; oxygen; carbon; and fluorine amounts; and a metal to fluorine ratio as defined herein; contacting the treated surface with an untreated or like-treated counterpart device substrate or glass carrier substrate to form a laminate comprised of the device substrate bonded to the glass carrier substrate; modifying at least a portion of the non-bonded second surface of the device substrate of the laminate with at least one device surface modification treatment; and separating the device substrate having the device modified second surface from the glass carrier substrate.

Disclosed herein are systems and methods for treating the surface of a microelectronic substrate, and in particular, relate to an apparatus and method for scanning the microelectronic substrate through a cryogenic fluid mixture used to treat an exposed surface of the microelectronic substrate. In particular, an improved nozzle design used to expand the fluid mixture is disclosed herein. In one embodiment, the nozzle design incorporates a two nozzle pieces are combined to form a single nozzle design, in which the two pieces are slight misaligned to form a unique orifice design. In another embodiment, two pieces are combined and aligned along a common axis of the fluid conduit. However, an offset piece is inserted between the two pieces and has a hole that misaligned from the flow conduits of the two other pieces.

The systems and methods discussed herein are for a cluster tool that can be used for MOSFET device fabrication, including NMOS and PMOS devices. The cluster tool includes process chambers for pre-cleaning, metal-silicide or metal-germanide film formation, and surface protection operations such as capping and nitridation. The cluster tool can include one or more process chambers configured to form a source and a drain. The devices fabricated in the cluster tool are fabricated to have at least one protective layer formed over the metal-silicide or metal-germanide film to protect the film from contamination during handling and transfer to separate systems.