A method of using a processing oven may include disposing at least one substrate in a chamber of the oven and activating a lamp assembly disposed above them to increase their temperature to a first temperature. A chemical vapor may be admitted into the chamber above the at least one substrate and an inert gas may be admitted into the chamber below the at least one substrate. The temperature of the at least one substrate may then be increased to a second temperature higher than the first temperature and then cooled down.

A monocrystalline silicon wafer fabricated such that a particular crystal plane, e.g., a crystal plane (100), included in crystal planes {100} is exposed on each of face and reverse sides of the monocrystalline silicon wafer is irradiated with a laser beam along a first direction parallel to the particular crystal plane and inclined to a particular crystal orientation, e.g., a crystal orientation [010], included in crystal orientations <100> at an angle of 5° or less, thereby forming a peel-off layer that functions as separation initiating points between a part of the monocrystalline silicon wafer that belongs to the face side thereof and a part of the monocrystalline silicon wafer that belongs to the reverse side thereof.

A method for processing a transparent workpiece includes forming a contour of defect in the transparent workpiece and separating the transparent workpiece along the contour using an infrared laser beam. During separation, the method also includes detecting a position and propagation direction of a crack tip relative to a reference location and propagation direction of an infrared beam spot, determining a detected distance and angular offset between the crack tip and the reference location of the infrared beam spot, comparing the detected distance to a preset distance, comparing the detected angular offset to a preset angular offset, and modifying at least one of a power of the infrared laser beam or a speed of relative translation between the infrared laser beam and the transparent workpiece in response to a difference between the detected distance and the preset distance and between the detected angular offset and the preset angular offset.

Provided is a method of manufacturing a semiconductor having a double-sided substrate including preparing a first substrate on which a specific pattern is formed to enable electrical connection, preparing at least one semiconductor chip bonded to a metal post, bonding the at least one semiconductor chip to the first substrate, bonding a second substrate to the metal post, forming a package housing by packaging the first substrate and the second substrate to expose a lead frame, and forming terminal leads toward the outside of the package housing. Accordingly, the semiconductor chip and the metal post are previously joined to each other and are respectively bonded to the first substrate and the second substrate so that damage generated while bonding the semiconductor chip may be minimized and electrical properties and reliability of the semiconductor chip may be improved.

According to claim 1, the invention relates to a method for providing at least one solid-body layer (4). The solid-body layer (4) is separated from a solid body (1). The method according to the invention preferably has the steps of: producing a plurality of modifications (9) in the interior of the solid body (1) using laser beams in order to form a separation plane (8), compressive stresses being produced in the solid body (1) by the modifications (9); separating the solid-body layer (4) by separating the remaining solid body (1) and the solid-body layer (4) along the separation plane (8) formed by the modifications (9), wherein at least parts of the modifications (9) which produce the compressive stresses remain on the solid-body layer (4), and enough modifications (9) are produced that the solid-body layer (4) is separated from the solid body (1) on the basis of the modifications (9) or an external force is introduced into the solid body (1) in order to produce additional stresses in the solid body (1), said external force being so great that the stresses cause a crack to propagate along the separation plane (8) produced by the modifications; and producing a metal layer on the surface exposed by the separation of the solid-body layer (4) from the solid body (1) in order to at least partly, preferably greatly and particularly preferably completely, compensate for a deformation of the solid-body layer (4) produced by the compressive stresses of the remaining modification parts or at feast partly, preferably greatly or completely, compensate for the compressive stresses.

A semiconductor die includes a substrate having a semiconductor surface layer bon a front side with active circuitry including at last one transistor therein and a back side. The sidewall edges of the semiconductor die have at least one damage region pair including an angled damage feature region relative to a surface normal of the semiconductor die that is above a damage region that is more normal to the surface normal of the die as compared to the angled damage feature region.

A laser processing device includes a control unit, and the control unit executes a first process of controlling a laser irradiation unit according to a first processing condition set such that a modified region and a modified region are formed inside a wafer; a second process of identifying a state related to each of the modified regions, and of determining whether or not the first processing condition is proper; a third process of controlling the laser irradiation unit according to a second processing condition set such that the modified regions are formed and a modified region is formed between the modified regions in a thickness direction of the wafer inside the wafer; and a fourth process of identifying a state related to each of the modified regions, and of determining whether or not the second processing condition is proper.

A wire bonding device for performing a wire bonding process includes: a bonding tool for inserting a wire; an ultrasonic vibrator; a drive mechanism for moving the bonding tool; and a control part. The control part performs: a bonding step of bonding the wire to a bonding point; a tail feeding out step of feeding out a wire tail from the wire bonded to the bonding point; a tension applying step of raising the bonding tool to apply tension to the wire while the wire is clamped; a tension release step of lowering the bonding tool to release the tension applied to the wire; and after performing a series of steps including the tension applying step and the tension release step at least once, a tail cutting step of raising the bonding tool to cut the wire tail from the wire.

This inspection device includes: a laser irradiation unit that irradiates a wafer having a back surface and a front surface with a laser beam from the back surface side of the wafer; an imaging unit that outputs light having permeability to the wafer and detects the light propagating through the wafer; and a control part configured to perform a first process of controlling the laser irradiation unit so that a modified region is formed inside the wafer by irradiating the wafer with the laser beam and a second process of deriving a position of the modified region on the basis of a signal output from the imaging unit that detects the light and deriving a thickness of the wafer on the basis of the derived position of the modified region and a set recipe.

A manufacturing method for wafers includes: radiating a laser beam to a planned cutoff surface where the ingot is to be cutoff; and forming, with the radiation of the laser beam, a plurality of reformed sections at the planned cutoff surface to extend a crack from the reformed section, thereby slicing wafers, wherein an energy density of the laser beam exceeds a reforming threshold. The energy density satisfies at least one of conditions of a peak value of the energy density is lower than or equal to 44 J/cm.sup.2, a rising rate of the energy density at a portion corresponding to the most shallow position where the energy density reaches the reforming threshold Eth is larger than or equal to 1000 J/cm.sup.3, and a range of depth where the energy density exceeds the reforming threshold is smaller than or equal to 30 μm.