A detection mechanism of a detection device includes a pulsed laser oscillator that emits a pulsed laser beam; an fθ lens facing a workpiece held by a chuck table; a thermal excitation section that applies the pulsed laser beam emitted from the pulsed laser oscillator to an upper surface of a wafer through the fθ lens and generates an ultrasonic wave propagated in a spherical form by thermal excitation; and an image forming section that forms an image by capturing a reflected laser beam influenced by vibration of the ultrasonic wave generated by the thermal excitation section, propagated through the inside of the workpiece, reflected by a lower surface of the workpiece, and returned to the upper surface of the workpiece, by an aperture synthesis method.

A device and method is described for producing an electrically conductive direct bond between a bonding side of a first substrate and a bonding side of a second substrate. A workspace is included that can be closed, gas-tight, against the environment and can be supplied with a vacuum. The workspace includes a) at least one plasma chamber for modifying at least one of the bonding sides and at least one bonding chamber for bonding the bonding sides, and/or b) at least one combined bonding/plasma chamber for modifying at least one of the bonding sides and for bonding the bonding sides.

A processing apparatus includes a processing unit grinding or polishing the reverse side, which is exposed upwardly, of a wafer, an infrared camera unit capturing an image of the wafer from the reverse side thereof and acquiring an image including the face side of the wafer, an information register having information on a pattern of structural objects which a wafer to be processed is to have on the face side, registered therein, and a determining unit determining that the wafer to be determined is a wafer to be processed if the pattern of structural objects which a wafer to be processed is to have on the face side is found on the wafer to be determined before being processed by the processing unit.

A protective member forming apparatus for forming a protective member on the top surface of a substrate by laminating a liquid resin and a cover sheet on a resin film includes: a liquid resin supply unit configured to supply the liquid resin onto the resin film; a pressing unit including a pressing surface, the pressing unit being configured to spread the liquid resin over the resin film by pressing the liquid resin by the pressing surface via the cover sheet; and a determining unit configured to determine the state of the spread liquid resin. The determining unit includes a determining section configured to determine whether or not the liquid resin is spread over a predetermined range with respect to the substrate.

A method for bonding a contact surface of a first substrate to a contact surface of a second substrate comprising of the steps of: positioning the first substrate on a first receiving surface of a first receiving apparatus and positioning the second substrate on a second receiving surface of a second receiving apparatus; establishing contact of the contact surfaces at a bond initiation site; and bonding the first substrate to the second substrate along a bonding wave which is travelling from the bond initiation site to the side edges of the substrates, wherein the first substrate and/or the second substrate is/are deformed for alignment of the contact surfaces.

Various embodiments process semiconductor devices. In one embodiment, a release layer is applied to a handler. The at least one singulated semiconductor device is bonded to the handler. The at least one singulated semiconductor device is packaged while it is bonded to the handler. The release layer is ablated by irradiating the release layer through the handler with a laser. The at least one singulated semiconductor device is removed from the transparent handler after the release layer has been ablated.

A technique is described in which a transistor formed using an oxide semiconductor film, a transistor formed using a polysilicon film, a transistor formed using an amorphous silicon film or the like, a transistor formed using an organic semiconductor film, a light-emitting element, or a passive element is separated from a glass substrate by light or heat. An oxide layer is formed over a light-transmitting substrate, a metal layer is selectively formed over the oxide layer, a resin layer is formed over the metal layer, an element layer is formed over the resin layer, a flexible film is fixed to the element layer, the resin layer and the metal layer are irradiated with light through the light-transmitting substrate, the light-transmitting substrate is separated, and a bottom surface of the metal layer is made bare.

The present disclosure, in some embodiments, relates to a workpiece bonding apparatus. The workpieces bonding apparatus includes a first substrate holder having a first surface configured to receive a first workpiece, and a second substrate holder having a second surface configured to receive a second workpiece. A vacuum apparatus is positioned between the first substrate holder and the second substrate holder and is configured to selectively induce a vacuum between the first surface and the second surface. The vacuum is configured to attract the first surface and the second surface toward one another.

In an embodiment, a chemical mechanical planarization (CMP) system includes: a monolithic platen within a platen housing, wherein the monolithic platen is formed of a single piece of material, wherein the monolithic platen includes: a first portion within a first opening, and a second portion within a second opening, wherein the first portion has a different diameter than the second portion; and a polishing fluid delivery module above the monolithic platen, wherein the polishing fluid delivery module is configured to deliver slurry to the monolithic platen during performance of CMP.

A substrate processing system configured to process a substrate includes a first modifying apparatus configured to form, in a combined substrate in which a front surface of a first substrate and a front surface of a second substrate are bonded to each other, an internal modification layer elongated within the first substrate in a plane direction from a center of the first substrate toward at least an edge portion of the first substrate as a removing target; a second modifying apparatus configured to form, within the first substrate, an edge modification layer elongated in a thickness direction of the first substrate along a boundary between the edge portion and a central portion of the first substrate; and a separating apparatus configured to separate a portion of the first substrate at a rear surface side, starting from the internal modification layer.