A method includes positioning a discrete component assembly on a support fixture of a component transfer system, the discrete component assembly including a dynamic release tape including a flexible support layer, and a dynamic release structure disposed on the flexible support layer, and a discrete component adhered to the dynamic release tape. The method includes irradiating the dynamic release structure to release the discrete component from the dynamic release tape.

A planarization system is provided. The planarization system includes a first substrate chuck which holds the substrate during a planarization step, and a second substrate chuck which holds the substrate with a non-flat configuration during a separation step.

Described is a semiconductor processing system including a measurement tool configured to measure warpage characteristics in a semiconductor wafer. The semiconductor processing system further includes a pixelated surface configured to retain the semiconductor wafer, where the pixelated surface approximates the warpage characteristics to conform to the semiconductor wafer. The semiconductor processing system further includes a semiconductor processing tool configured to perform processing on the semiconductor wafer while it is retained on the pixelated surface.

A substrate processing apparatus configured to process a combined substrate in which a first substrate and a second substrate are bonded to each other includes a holding member configured to hold the combined substrate; a removing member configured to separate at least a peripheral portion of the first substrate from the second substrate by being inserted between the first substrate and the second substrate; an elevating mechanism configured to adjust a relative height position of the removing member with respect to the holding member; and a controller configured to control an operation of the elevating mechanism. The controller controls the operation of the elevating mechanism such that the relative height position of the removing member with respect to a target insertion position of the removing member is adjusted in an entire circumference of the combined substrate.

An apparatus and method for debonding a pair of bonded wafers are disclosed herein. In some embodiments, the debonding apparatus, comprises: a wafer chuck having a preset maximum lateral dimension and configured to rotate the pair of bonded wafers attached to a top surface of the wafer chuck, a pair of circular plate separating blades including a first separating blade and a second separating blade arranged diametrically opposite to each other at edges of the pair of bonded wafers, wherein the first and the second separating blades are inserted between a first and a second wafers of the pair of bonded wafers, and at least two pulling heads configured to pull the second wafer upwardly so as to debond the second wafer from the first wafer.

The present disclosure is to provide a wafer carrier substrate for carrying a wafer on which a plurality of chips is formed, elements to be measured being built in the plurality of chips. The wafer carrier substrate includes: a vacuuming hole for vacuuming of the wafer placed on the wafer carrier substrate; a wafer alignment guide for determining a predetermined position of the wafer placed on the wafer carrier substrate; and a mark for determining a probe contact position. It is possible to recognize a specific shot, without any additional processing of the semiconductor wafer.

A lithographic apparatus substrate table comprises a plurality of first projections, whereby the first projections define a first substrate supporting plane and a plurality of second projections, whereby the second projections define a second substrate supporting plane. The substrate table further comprises a clamping device configured to exert a clamping force onto the substrate. The second substrate supporting plane is parallel to the first substrate supporting plane. The second substrate supporting plane is offset in respect of the first substrate supporting plane in a direction perpendicular to the first and second substrate supporting planes. The lithographic apparatus substrate table is configured to support the substrate on the second projections at the second substrate supporting plane before application of the clamping force by the clamping device. The second projections are configured to deform upon application by the clamping device of the clamping force onto the substrate, thereby providing the substrate to move from the second substrate supporting plane to the first substrate supporting plane when clamped by the clamping device.

A lithographic apparatus substrate table comprises a plurality of first projections, whereby the first projections define a first substrate supporting plane and a plurality of second projections, whereby the second projections define a second substrate supporting plane. The substrate table further comprises a clamping device configured to exert a clamping force onto the substrate. The second substrate supporting plane is parallel to the first substrate supporting plane. The second substrate supporting plane is offset in respect of the first substrate supporting plane in a direction perpendicular to the first and second substrate supporting planes. The lithographic apparatus substrate table is configured to support the substrate on the second projections at the second substrate supporting plane before application of the clamping force by the clamping device. The second projections are configured to deform upon application by the clamping device of the clamping force onto the substrate, thereby providing the substrate to move from the second substrate supporting plane to the first substrate supporting plane when clamped by the clamping device.

An apparatus for manufacturing a semiconductor package is provided. The apparatus includes: a chuck configured to hold an object, wherein the object includes a wafer-to-wafer bonding structure, the wafer-to-wafer bonding structure includes an edge area, and a gap is defined in the edge area between wafers; and a supply structure configured to dispense a sealant toward the gap of the wafer-to-wafer bonding structure while held in a vertical orientation.

A wafer handling device is configured to transport a wafer tray. The wafer handling device includes a sucker module and a transporting apparatus. The sucker module includes a sucker body, at least one airtight assembly, and a pump. The sucker body includes a first portion and a second portion. The first portion has a hole and a first air sucking hole. The second portion has a second air sucking hole. The airtight assembly is connected to the hole. The pump has a suction tube connected to the first air sucking hole and the second air sucking hole. The transporting apparatus is configured to move the sucker body. When the sucker body is connected to the wafer tray, the first portion, the second portion, and the wafer tray form an airtight space.