Abstract:
Embodiments of a wafer cleaning system and method are provided. A brush element is configured to clean a backside of the wafer. The backside has a clear area and an unclear area, and some contaminants are located in the unclear area. A control device performs a first cleaning process to the brush element when the brush element is located at the clear area, and the control device performs a second cleaning process when the brush element is located at the unclear area. The contaminants are cleaned by an enhanced cleaning process. Since the contaminants are cleaned, the backside of the wafer is flatter, and quality of the exposed photoresist on the wafer is improved.
Abstract:
Embodiments of mechanisms for processing a wafer are provided. A method for processing a wafer includes placing the wafer into a processing assembly and heating the wafer. The method also includes producing an exhaust flow from the processing assembly via a fluid-conduit assembly. The method further includes detecting an exhaust pressure of the exhaust flow in the fluid-conduit assembly and producing a first signal and a second signal corresponding to the exhaust pressure. In addition, the method includes regulating the exhaust flow in response to the first signal and controlling the processing assembly in response to the second signal.
Abstract:
A method for fault detection in a fabrication facility is provided. The method includes moving a wafer carrier using a transportation apparatus. The method further includes measuring an environmental condition within the wafer carrier or around the wafer carrier using a metrology tool positioned on the wafer carrier during the movement of the wafer carrier. The method also includes issuing a warning when the detected environmental condition is outside a range of acceptable values.
Abstract:
A method for fault detection in a fabrication system is provided. The method includes transferring a reticle carrier containing a reticle from an original position to a destination position. The method further includes detecting environmental condition in the reticle carrier during the transfer of the reticle carrier using a metrology tool that is positioned at the reticle carrier. The method also includes issuing a warning when the detected environmental condition is outside a range of acceptable values.
Abstract:
Embodiments of a photoresist supply system including a photoresist nozzle device are provided. The photoresist nozzle device includes a tube including a first segment, a curved segment connected to the first segment, and a second segment connected to the curved segment. The photoresist nozzle device also includes a nozzle connected to the second segment.
Abstract:
A wafer cleaning system and method are provided. A brush element is configured to clean a backside of the wafer. The backside has a clear area and an unclear area, and some contaminants are located in the unclear area. A control device performs a first cleaning process to the brush element when the brush element is located at the clear area, and the control device performs a second cleaning process when the brush element is located at the unclear area. The contaminants are cleaned by an enhanced cleaning process. Since the contaminants are cleaned, the backside of the wafer is flatter, and quality of the exposed photoresist on the wafer is improved.
Abstract:
A cup-wash device is provided. The cup-wash device includes a supporting disk and a base disposed on the supporting disk. The base includes a catchment groove, a first dispensing opening formed on an edge of the base, and a first channel connected with the catchment groove and the first dispensing opening. The cup-wash device also includes a cover disposed on the base and covering the first channel, and the cover has an injection opening connected to the catchment groove.
Abstract:
A brush for back surface treatment (BST) is provided. The brush includes a base portion and a brushing portion. The brushing portion is connected to the base portion. The brushing portion has a plurality of gutters disposed on a surface away from the base portion, in which at least one of the gutters has at least one open end located at least partially on a perimeter of the surface.
Abstract:
A UV curing system includes an enclosure defining an interior, a UV radiation source disposed within the interior of the enclosure, and a first window disposed within the interior of the enclosure. The first window creates a barrier that separates the UV radiation source and a processing chamber. A second window is disposed within the interior of the enclosure at a distance from the first window to define a gas channel. The second window defines a plurality of openings such that the gas channel is in fluid communication with the processing chamber. A gas inlet conduit is in fluid communication with the gas channel and is configured to introduce a cooling gas into the gas channel. A gas outlet is in fluid communication with the processing chamber and is configured to remove gas from the processing chamber.
Abstract:
A lithography includes a storage tank that stores process chemical fluid, an anti-collision frame, and an integrated sensor assembly. The storage tank includes a dispensing port positioned at a lowest part of the storage tank in a gravity direction. The anti-collision frame is coupled to the storage tank. An integrated sensor assembly is disposed on at least one of the anti-collision frame and the storage tank to measure a variation in fluid quality in response to fluid quality measurement of fluid.