A manufacturing method of a chip-attached substrate includes preparing a stacked substrate including multiple chips, a first substrate to which the multiple chips are temporarily bonded, and a second substrate bonded to the first substrate with the multiple chips therebetween; and separating the multiple chips bonded to the first substrate and the second substrate from the first substrate to bond the multiple chips to one surface of a third substrate including a device layer.

A substrate processing method of processing a combined substrate in which a first substrate and a second substrate are bonded to each other includes forming a peripheral modification layer along a boundary between a peripheral portion of the first substrate as a removing target and a central portion of the first substrate; forming a non-bonding region in which bonding strength between the first substrate and the second substrate in the peripheral portion is reduced; and removing the peripheral portion starting from the peripheral modification layer. A first crack is developed from the peripheral modification layer toward the second substrate. The peripheral modification layer is formed such that a lower end of the first crack is located above the non-bonding region and an inner end of the non-bonding region is located at a diametrically outer side than the first crack.

Provided is a silica glass disc in which the deformation amount thereof in heat treatment is minimized, and the surface area of a silica glass surface can be increased. There is provided a silica glass disc, including a dimple forming area in which a large number of dimples are formed on at least one of a front surface or a back surface of a silica glass body, and the dimples in the dimple forming area are regularly formed. It is preferred that the dimples be formed by a laser.

An element chip manufacturing method includes a step of preparing a substrate including a semiconductor layer and a wiring layer formed on the semiconductor layer and having a plurality of element regions and a dicing region defining the element regions, a laser grooving step of irradiating a laser beam to the wiring layer at the dicing region, to form an aperture exposing the semiconductor layer, and an individualization step of etching the semiconductor layer exposed from the aperture, with plasma, to divide the substrate into a plurality of element chips. The laser grooving step including a step of irradiating a first laser beam, to form a first groove exposing the semiconductor layer in the dicing region, and a step of irradiating a second laser beam, with a beam center positioned outside a side wall of the first groove, to widen the first groove into the aperture.

An operation accuracy measuring method for measuring the operation accuracy of a linear motion mechanism includes the steps of placing on a support table a measuring jig having a flat lower surface, a parallel surface opposite and parallel to the lower surface, and a slanted surface joined to the parallel surface through a straight boundary line, adjusting the position of the measuring jig to allow the white light interferometer to observe the parallel surface and the slanted surface simultaneously, capturing images of the parallel surface and the slanted surface with the white light interferometer and observing changes in interference fringes appearing in image sections of the captured images that represent the parallel surface and the slanted surface while the support table is being linearly moved, and the step of deducing the operation accuracy of the linear motion mechanism on the basis of the observed changes in the interference fringes.

A control unit of a processing apparatus detects a linear region corresponding to a first planned dividing line from an intersection region of the first planned dividing line and a second planned dividing line, obtains an angle between the linear region and an X-axis direction, and positions the linear region corresponding to the first planned dividing line in the X-axis direction. A linear region corresponding to a next first planned dividing line is detected and an interval between the first planned dividing lines is set. A second planned dividing line interval setting section detects two linear regions corresponding to second planned dividing lines, the linear regions being adjacent to each other, and an interval is set between the second planned dividing lines. A device image enclosed by a pair of first planned dividing lines and a pair of second planned dividing lines is generated and stored.

A manufacturing method for a device chip includes a wafer preparation step of preparing a wafer including a base substrate, a laser beam absorbing layer layered on a front surface of the base substrate, and a device layer being layered on the laser beam absorbing layer and having devices formed in respective separate regions demarcated by a plurality of crossing division lines, a device layer dividing step of forming respective division grooves that divide at least the device layer into individual device chips along the plurality of division lines, and a lift-off step of, after the device layer dividing step is carried out, applying a laser beam of such a wavelength as to be absorbed in the laser beam absorbing layer, from the base substrate side, and lifting off a device chip from the front surface of the base substrate.

Exemplary methods of cooling a semiconductor component substrate may include heating the semiconductor component substrate to a temperature of greater than or about 500° C. in a chamber. The semiconductor component substrate may be or include aluminum. The methods may include delivering a gas into the chamber. The gas may be characterized by a temperature below or about 100° C. The methods may include cooling the semiconductor component substrate to a temperature below or about 200° C. in a first time period of less than or about 1 minute.

Data received from an in-situ monitoring system includes, for each scan of a sensor, a plurality of measured signal values for a plurality of different locations on a layer. A thickness of a polishing pad is determined based on the data from the in-situ monitoring system. For each scan, a portion of the measured signal values are adjusted based on the thickness of the polishing pad. For each scan of the plurality of scans and each location of the plurality of different locations, a value is generated representing a thickness of the layer at the location. This includes processing the adjusted signal values using one or more processors configured by machine learning. A polishing endpoint is detected or a polishing parameter is modified based on the values representing the thicknesses at the plurality of different locations.

A substrate processing method includes a processing liquid supplying step of supplying a processing liquid having a solute and a solvent to a surface of a substrate, a processing film forming step of solidifying or curing the processing liquid supplied to the surface of the substrate to form, on the surface of the substrate, a processing film that holds a removal object present on the surface of the substrate, a peeling step of supplying a peeling liquid forming liquid to the surface of the substrate to put the peeling liquid forming liquid in contact with the processing film and form a peeling liquid, and peeling the processing film, in the state of holding the removal object, from the surface of the substrate by the peeling liquid, and a removing step of continuing the supply of the peeling liquid forming liquid, after the peeling of the processing film, to wash away and remove the processing film from the surface of the substrate in the state where the removal object is held by the processing film.