A substrate is held in a horizontal attitude by a substrate holder. At a processing position, a lower surface of the substrate held by the substrate holder is cleaned by a lower-surface brush. The lower-surface brush is cleaned by a brush cleaner at a waiting position that overlaps with the substrate held by the substrate holder in an up-and-down direction and is below a processing position. The lower-surface brush is lifted and lowered by a lower-surface brush lifting-lowering driver between the processing position and the waiting position.

According to one embodiment of the present disclosure, provided is a substrate cleaning device including: a substrate holder configured to hold a substrate; a substrate cleaning member configured to come into sliding contact with the held substrate, and clean the substrate using a first cleaning liquid supplied from a first nozzle; a self-cleaning member configured to come into sliding contact with the substrate cleaning member at a retreat position separated from the substrate holder, and performs self-cleaning on the substrate cleaning member using a second cleaning liquid supplied from a second nozzle; a measurement module configured to measure a physical property value of a waste liquid of the second cleaning liquid used for the self-cleaning of the substrate cleaning member; and a controller configured to estimate a number of fine particles adhering to the cleaned substrate based on the physical property value of the waste liquid.

The disclosure provides a jig for attaching and detaching a cleaning member, which facilitates attaching and detaching the cleaning member to and from a rotation device without holding the cleaning member directly by hand, even when there is no sufficient spacing around the cleaning member. The jig 100 for attaching and detaching a cleaning member 60 includes a pair of jig bodies 110 capable of clamping two ends 63 of a holder 62 of the cleaning member 60, and a connecting mechanism 120 that interlocks the movements of the pair of jig bodies 110 between a clamped state in which two ends 63 of the holder 62 are clamped and a non-clamped state in which the clamped state is released.

A substrate cleaning device that facilitates control of the amount of liquid supplied to a substrate and reduces adverse influences of the liquid supplied to a bearing part on the substrate is provided. The substrate cleaning device includes: a holding part that has a bearing part configured to rotatably hold a cleaning member for cleaning a substrate; a first supply part that has at least a part provided inside the holding part and supplies a first liquid into the cleaning member through the inside of the holding part; and a second supply part that supplies a second liquid to the bearing part.

Wafers that begin as flat surfaces during a semiconductor manufacturing process may become warped or bowed as layers and features are added to an underlying substrate. This warpage may be detected between manufacturing processes by rotating the wafer adjacent to a displacement sensor. The displacement sensor may generate displacement data relative to a baseline measurement to identify areas of the wafer that bow up or down. The displacement data may then be mapped to locations on the wafer relative to an alignment feature. This mapping may then be used to adjust parameters in subsequent semiconductor processes, including adjusting how a carrier head on a polishing process holds or applies pressure to the wafer as it is polished.

The present application relates to the field of semiconductors and discloses a cleaning device and a cleaning method. The cleaning device comprises a bearing mechanism for supporting an object to be cleaned in a preset direction, and a cleaning mechanism for cleaning the object to be cleaned, the cleaning mechanism comprising a base and a first cleaning member detachably disposed on the base. The first cleaning member comprises a housing for detachably connecting with the base and a first brush head portion disposed on the housing, an accommodating space being formed and surrounded by the housing and the first brush head portion. A second cleaning member is further disposed on the base, the second cleaning member being accommodated in the accommodating space.

A semiconductor manufacturing equipment cleaning system has a multi-station cleaning and inspection system. Within semiconductor manufacturing equipment cleaning system, a tray cleaning station uses a first rotating brush passing over a first surface of a carrier and possibly semiconductor die, and a second rotating brush passing over a second surface of the carrier and semiconductor die opposite the first surface of the carrier and semiconductor die. Debris and contaminants dislodged from the first surface and second surface of the carrier by the first rotating brush and second rotating brush are removed under vacuum suction. A conveyor transports the carrier through the multi-station cleaning and inspection system. The first rotating brush and second rotating brush move in tandem across the first surface and second surface of the carrier. Air pressure is injected across the first rotating brush and second rotating brush to further remove debris and contaminants.

Provided is a substrate cleaning apparatus including: a substrate support mechanism configured to support a substrate; and a roll-type first cleaning member configured to clean a first surface of the substrate by rotating while being in contact with a bevel and/or an edge of the first surface of the substrate, wherein a rotation axis of the first cleaning member is in parallel with the substrate, and the first cleaning member has a large diameter portion and a small diameter portion.

A tool and methods of removing films from bevel regions of wafers are disclosed. The bevel film removal tool includes an inner motor nested within an outer motor and a bevel brush secured to the outer motor. The bevel brush is adjustable radially outward to allow the wafer to be inserted in the bevel brush and to be secured to the inner motor. The bevel brush is adjustable radially inward to engage one or more sections of the bevel brush and to bring the bevel brush in contact with a bevel region of the wafer. Once engaged, a solution may be dispensed at the engaged sections of the bevel brush and the inner motor and the outer motor may be rotated such that the bevel brush is rotated against the wafer such that the bevel films of the wafer are both chemically and mechanically removed.

A wafer carrier includes a pocket sized and shaped to accommodate a wafer, the pocket having a base and a substantially circular perimeter, and a removable orientation marker, the removable orientation marker comprising an outer surface and an inner surface, the outer surface having an arcuate form sized and shaped to mate with the substantially circular perimeter of the pocket, and the inner surface comprising a flat face, wherein the removable orientation marker further comprises a notch at a first end of the flat face.