A controller of a laser processing apparatus includes: a storage section that stores processing conditions for forming modified layers along division lines of a wafer; and a processing line calculation section that displays a position at which the modified layer is planned to be formed and which is stored as the processing condition, on a display panel as a processing line. The processing line calculation section displays the processing line on the display panel superimposed on a first division line, in a region in which a start point or end point of the first division line is connected to a second division line. A start point or end point of a first modified layer formed along the first division line is permitted to be re-set on the display panel so as not to interfere with a second modified layer formed along the second division line.

A control device of a semiconductor manufacturing apparatus includes a processor and a memory connected to the processor and storing instructions executable by the processor. The instructions collect a sound of processing a substrate by the semiconductor manufacturing apparatus. The instructions calculate a difference of a power spectrum of the processing sound between a first point of time and a second point of time. The instructions determine a change point of processing of the substrate based on the difference.

In accordance with some embodiments, a wafer taping device is provided. The wafer taping device includes a tape delivering along a first direction. The wafer taping device also includes a wafer mount unit disposed below the tape. The wafer mount unit has an upper surface for supporting a wafer and having a notch for allowing a cut mark of the wafer to align with it. The notch is staggered with a second direction in the upper surface, and the second direction is substantially perpendicular to the first direction. In addition, the wafer taping device includes a laminating roller disposed above the wafer mount unit and having a long axis elongated in the second direction. The laminating roller is configured to reciprocate along the first direction for pressing the tape to the wafer.

Semiconductor wafers with improved geometry are produced from a workpiece by processing the workpiece by means of a wire saw, by feeding the workpiece through an arrangement of wires which are tensioned between wire guide rollers and move in a running direction; producing kerfs when the wires engage into the workpiece; determining a placement error of the kerfs; and inducing a compensating movement of the workpiece as a function of the determined placement error along a longitudinal axis of the workpiece during the feeding of the workpiece through the arrangement of wires.

A fixture used in the manufacture of an eyepiece, to cut the eyepiece to a particular shape, and a method of using the fixture to cut the eyepiece to have a desired shape. Embodiments are directed to a configurable fixture to align, hold, and protect a plastic sheet (e.g., a wafer) while a laser cutting apparatus is cutting one or more eyepieces out of the wafer. During the cutting, the fixture protects the eyepieces from reflected laser light by providing voids around the laser cutting lines, and by supporting each eyepiece near its perimeter. The fixture can be quickly rearranged for different eyepieces, different eyepiece shapes, and/or different plastic sheet sizes.

A substrate processing apparatus includes a holder configured to hold a combined substrate; a peripheral modifying device configured to form a peripheral modification layer to an inside of a first substrate along a boundary between a peripheral portion and a central portion; an internal modifying device configured to form an internal modification layer to the inside of the first substrate along a plane direction; a holder moving mechanism configured to move the holder in a horizontal direction. The peripheral modifying device radiates laser light for periphery to the inside of the first substrate while moving the holder to perform eccentricity correction. The internal modifying device radiates laser light for internal surface without performing the eccentricity correction at least at a center portion of the inside of the first substrate.

A substrate processing apparatus configured to process a substrate includes a substrate holder configured to hold, 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, the second substrate; a periphery modification unit configured to form a peripheral modification layer by radiating laser light for periphery to an inside of the first substrate held by the substrate holder along a boundary between a peripheral portion of the first substrate as a removing target and a central portion thereof; and an internal modification unit configured to form, after the peripheral modification layer is formed by the periphery modification unit, an internal modification layer by radiating laser light for internal surface to the inside of the first substrate held by the substrate holder along a plane direction of the first substrate.

A method includes measuring a topography of a wafer, determining that a first portion of the wafer has a greater thickness than a specified thickness. The method further includes, after measuring the wafer, performing a Chemical Mechanical Polishing (CMP) process to a first side of the wafer, and during application of the CMP process, applying additional pressure to a region of the wafer, the region comprising an asymmetric part of the wafer, the region including at least a part of the first portion of the wafer.

Embodiments of apparatus and method for chemical mechanical polishing (CMP) are disclosed. In an example, an apparatus for CMP includes a platen, a slurry supply, and at least one scraping fixture. The platen is configured to rotate a pad thereon about a central axis of the pad. The slurry supply is configured to supply a slurry onto the pad while the pad rotates. The at least one scraping fixture is configured to scrape the slurry off the pad when the slurry travels a distance between the slurry supply and the at least one scraping fixture in a circumferential direction of the pad as the pad rotates.

A bonding device has two chucks, two gas pressure regulators and a control unit. The chucks each have a holding surface with pressure ports fluidically connected to the respective gas pressure regulator. The control unit is electrically and/or wirelessly connected to the gas pressure regulators and configured to control gas pressure regulators independently from each other. Support elements movably mounted within the pressure ports, are provided to measure the amount of substrate deflection and adjust the respective gas pressures and also to apply additional mechanical pressure to the substrates. The two chucks may be mounted on corresponding support structures so as to be thermally isolated therefrom. The temperature of the two chucks may be equalised by moving the chucks into contact. A chuck tempering device may be used for equalising the temperature of the two chucks. The bonding device is used for bonding two substrates by bonding wave propagation.