Methods for singulating an optical waveguide material at a contour include directing a first laser beam onto a first side of the optical waveguide material to generate a first group of perforations in the optical waveguide material. A second laser beam is directed onto a second side of the optical waveguide material to generate a second group of perforations in the optical waveguide material. The second side is opposite the first side. The first group of perforations and the second group of perforations define a perforation zone at the contour. A third laser beam is directed at the perforation zone to singulate the optical waveguide material at the perforation zone.

A method and apparatus for substrate dicing are described. The method includes utilizing a laser to dice a substrate along a dicing path to form a perforated line around each device within the substrate. The dicing path is created by exposing the substrate to bursts of laser pulses at different locations around each device. The laser pulses are delivered to the substrate and may have a pulse repetition frequency of greater than about 25 MHz, a pulse width of less than about 15 picoseconds, and a laser wavelength of about 1.0 μm to about 5 μm.

A method of producing a glass substrate having a hole is provided. The method includes preparing the glass substrate having a first surface and a second surface facing each other; forming a hole in the glass substrate with a laser; and annealing the glass substrate placed on a first support substrate having a thermal expansion coefficient whose difference from a thermal expansion coefficient of the glass substrate is less than or equal to 1 ppm/K, where the first support substrate is placed on a second support substrate having a thermal expansion coefficient of less than or equal to 10 ppm/K.

Apparatus and methods are disclosed for transferring solder to a substrate. A substrate belt moves one or more substrates in a belt direction. A decal has one or more through holes in a hole pattern that hold solder. Each of the solder holes can align with respective locations on one of the substrates. An ultrasonic head produces an ultrasonic vibration in the solder in a longitudinal direction perpendicular to the belt direction. The ultrasonic head and substrate can be moved together in the longitudinal direction to maintain the ultrasonic head in contact with the solder while the ultrasonic head applies the ultrasonic vibration. Various methods are disclosed including methods of transferring the solder with or without external heating.

A self-shielded flux-cored welding wire with a special protective slag coating formed in situ and a manufacture method thereof. The self-shielded flux-cored welding wire includes a low-carbon steel belt and a flux core powder, the flux core powder is filled in the low-carbon steel belt, the flux core powder includes the following ingredients in percentage by mass: 60-80% glass powder, 2-8% zirconium oxide powder, 0.05-0.85% graphene powder, 2-8% potassium carbonate sodium powder, 1-3% potassium titanate powder, 2-5% rutile powder, 1-5% corundum powder, 1-3% sodium fluorosilicate powder, and the balance of iron powder, and a weight of the flux core powder accounts for 13-25% of a total weight of the welding wire.

The invention provides an apparatus for creating a hole in a glass container with a medium stored therein, comprising: a laser system configured to focus laser pulses with a wavelength in the ultraviolet regime onto the glass container such as to create a hole in the glass container by laser ablation preferably without creating significant amounts of glass particles inside and outside the glass container.

A method for producing a cavity in a substrate composed of hard brittle material is provided. A laser beam of an ultrashort pulse laser is directed a side surface of the substrate and is concentrated by a focusing optical unit to form an elongated focus in the substrate. Incident energy of the laser beam produces a filament-shaped flaw in a volume of the substrate. The filament-shaped flaw extends into the volume to a predetermined depth and does not pass through the substrate. To produce the filament-shaped flaw, the ultrashort pulse laser radiates in a pulse or a pulse packet having at least two successive laser pulses. After at least two filament-shaped flaws are introduced, the substrate is exposed to an etching medium which removes material of the substrate and widens the at least two filament-shaped flaws to form filaments. At least two filaments are connected to form a cavity.

The invention relates to a method for manufacturing a hollow glass article including a step of marking the hollow glass article thus formed by laser, the surface of the hollow glass article being at a temperature between 400° C. and 600° C. The marking step consists in making filiform decorations by producing at least one continuous and shiny groove on the surface of the hollow glass article.

Provided are a laser control structure and a laser bonding method using the same, and more particularly, a laser bonding method including: forming bonding portions on a substrate; providing a bonding object onto the bonding portions; providing a laser control structure onto the bonding object or the substrate; irradiating a laser toward the bonding object and the bonding portions; controlling quantity of laser light absorbed through the laser control structure; using the controlled quantity of laser light to heat the bonding portions and the bonding object to a bonding temperature; and bonding the bonding portions and the bonding object, wherein the laser control structure includes: a first substrate including a first region and a second region; a first thin film laminate on the first region; and a second thin film laminate on the second region, wherein: the first thin film laminate includes at least one first thin film layer and at least one second thin film layer, which are laminated on the first region; the second thin film laminate includes at least one third thin film layer and at least one fourth thin film layer, which are laminated on the second region; reflectance or absorptivity of the first thin film laminate with respect to laser is different from reflectance or absorptivity of the second thin film laminate; and the bonding temperature varies according to the quantity of laser light.

An article is produced by welding a first piece to a second piece by a laser beam. The first piece includes an open cavity and a first sealing surface. The second piece has a second sealing surface. The first piece and second piece are inside chamber with a controllable internal pressure that is changed to cause a flow of a gas from the open cavity. The open cavity is closed by moving at least one of the pieces. The first sealing surface forms a partially gas tight preliminary joint with the second sealing surface. The first piece and the second piece define an interface. The chamber is opened after the preliminary joint has been formed. A welded seam is formed by focusing a laser beam to the interface after the chamber is opened. The first sealing surface and the second sealing surface are substantially planar.