A wafer processing method for divides a wafer into individual device chips along a plurality of division lines. The method includes forming a dividing groove along each division line formed on the front side of the wafer, the dividing groove having a depth corresponding to the finished thickness of each device chip, thinning the wafer to expose the dividing groove to the back side of the wafer, thereby dividing the wafer into the individual device chips, applying a liquid resin for die bonding to the back side of the wafer and next solidifying the liquid resin applied to the back side of the wafer, thereby forming a die bonding resin film having a predetermined thickness on the back side of each device chip, and isolating each device chip from the wafer.

An imprint apparatus forms a pattern on an imprint region of a substrate by bringing a mold into contact with an imprint material on the imprint region and curing the imprint material. The apparatus includes a controller for controlling an alignment operation of adjusting relative position between the mold and the imprint region in a state that the mold is in contact with the imprint material. The alignment operation includes a translation operation of performing relative translation between the imprint region and the mold, and a rotation operation of performing relative rotation between the imprint region and the mold. The rotation operation includes a first operation and a second operation, and a relative rotation direction between the imprint region and the mold in the second operation is opposite to a relative rotation direction between the imprint region and the mold in the first operation.

A wafer processing method includes a polyester sheet providing step of positioning a wafer in an inside opening of a ring frame and providing a polyester sheet on a back side or a front side of the wafer and on a back side of the ring frame, a uniting step of heating the polyester sheet as applying a pressure to the polyester sheet to thereby unite the wafer and the ring frame through the polyester sheet by thermocompression bonding, a dividing step of applying a laser beam to the wafer to form modified layers in the wafer, thereby dividing the wafer into individual device chips, and a pickup step of heating the polyester sheet in each of the plurality of separate regions corresponding to each device chip, pushing up each device chip through the polyester sheet, then picking up each device chip from the polyester sheet.

A workpiece-separating device includes a holding member configured to detachably hold one of a workpiece or a supporting body of a laminated body and a light irradiation part configured to perform light irradiation on a separating layer, the holding member including: a stage facing one of the workpiece or the supporting body, a fixed supporting part projecting from the stage toward the laminated body and including a still suction pad immovable in a projection direction, and a movable supporting part projecting from the stage toward the laminated body and including a response suction pad that is movable in a projection direction and elastically deformable, a plurality of the fixed supporting parts and a plurality of the movable supporting parts disposed in a dispersed manner, and the plurality of response suction pads project toward the laminated body further than the plurality of still suction pads.

Provided are an apparatus for manufacturing a semiconductor device and a method of manufacturing a semiconductor package using the same. The manufacturing apparatus may include a base with a plurality of through holes and weight blocks respectively bound by the through holes.

According to various embodiments, a workpiece planarization arrangement may include: a chuck including at least one portion configured to support one or more workpieces; and a planarization tool configured to planarize the at least one portion of the chuck and to planarize one or more workpieces on the at least one portion of the chuck; wherein the at least one portion of the chuck includes at least one of particles, pores and/or a polymer.

An end-point detection sensor 50 detects an end point of polishing, the end-point detection sensor 50 being arranged in a polishing table 100. The end-point detection sensor 50 has a pot core. The pot core 60 has a bottom portion 61a, a magnetic core base portion 61b and a peripheral wall base portion 61c. The end-point detection sensor 50 has an exciting coil 62, and a detection coil 63. The back surface 101b of the polishing pad 101 has a space 30 which is arranged at a portion facing the polishing table 100 and houses a magnetic core extension portion 8 and a peripheral wall extension portion 11. The magnetic core extension portion 8 and the peripheral wall extension portion 11 extending to the space 30 are located in the space 30.

A system for zapping a wafer, the system may include a pulse generation unit that is configured to generate (a) first zapping pulses for causing a breakdown in a first location of a backside insulating layer of a wafer, and (b) second zapping pulses for causing a breakdown in a second location of the backside insulating layer of the wafer; a first conductive interface that is configured to convey the first zapping pulses to the first location, while contacting the first location; a second conductive interface that is configured to convey the second zapping pulses to the second location, while contacting the second location; and wherein the first location differs from the second location.

An apparatus for manufacturing a display device includes a first jig including a first side, the first side having a concave groove for receiving a cover window, wherein the cover window includes a first planar portion, a first curved portion and a second curved portion, wherein the first and second curved portions are disposed at opposite ends of the first planar portion in a first direction, a second jig including a planar side for receiving a display panel, wherein when the second jig is moved in a second direction crossing the first direction with the display panel on the planar side, the display panel is disposed between the first and second curved portions of the cover window, and a pair of third jigs for supporting the first and second curved portions of the cover window.

According to various embodiments, a workpiece planarization arrangement may include: a chuck including a support carrier; and a workpiece-support replaceably mounted on the support carrier; and a planarization tool configured to planarize the at least one portion of the workpiece-support and to planarize one or more workpieces on the at least one portion of the workpiece-support.