Abstract: A coating material containing metal oxide is applied to one side of a substrate, both coating and substrate being transparent to visible light. An absorber material is placed in heat transfer proximity to the coating and a laser beam is transmitted through the substrate and through the coating to strike the absorber material at the interface between coating and absorber. The absorber material absorbs optical energy from the laser beam causing the material to heat. Heat from the absorber propagates to the coating to heat a localized region, causing the coating material to anneal. If desired, the coating material can include a doping material that fuses into the coating during annealing.

Abstract: Certain embodiments of the invention may include systems and methods curing a coated optical fiber. The method includes drawing the coated optical fiber through a gas chamber filled with a predetermined gas, drawing the fiber through a cure tube coupled to the gas chamber, and purging at least a portion of an inner surface of the cure tube with a purge gas as the coated optical fiber is drawn through the cure tube.

Abstract: Provided are a method of heating a composition which is applicable to a substrate provided with a material having low heat resistance and a method of forming a glass pattern which leads to reduction of cracks. A composition formed over a substrate is irradiated with a laser beam to bake the paste through local heating. Scan with the laser beam is performed so that there can be no difference in the laser beam irradiation period between the middle portion and the perimeter portion of the composition. Specifically, irradiation with the laser beam is performed so that the width of the beam spot overlapping with the composition in the scanning direction is substantially uniform.

Abstract: A method and apparatus for treatment of a substrate surface using an atmospheric pressure plasma is disclosed. The method comprises providing an atmospheric pressure plasma in a treatment space between a first electrode and a second electrode, providing a substrate in contact with the first electrode in the treatment space, and applying a plasma generating power to the first and second electrodes. The first electrode has a predefined structure of insulating areas and conductive areas for plasma treatment of surface areas of the substrate corresponding to the areas in contact with the conductive areas of the first electrode.

Abstract: The invention relates to a method for producing a getter device (1), wherein a getter material (3) is introduced into a container (2) and the getter material (3) is heated to a temperature under reduced pressure so that getter material (3) is deposited on an inside of the container (2). In order to be able to provide a getter device (1) in a short time that has a high getter capacity, it is provided according to the invention that during a deposition of getter material (3), the container (2) is moved relative to a zone (4) in which the container (2) is cooled.

Abstract: Methods of fabricating coated components using multiple types of fillers are provided. One method comprises forming one or more grooves in an outer surface of a substrate. Each groove has a base and extends at least partially along the outer surface of the substrate. The method further includes disposing a sacrificial filler within the groove(s), disposing a permanent filler over the sacrificial filler, disposing a coating over at least a portion of the substrate and over the permanent filler, and removing the first sacrificial filler from the groove(s), to define one or more channels for cooling the component. A component with a permanent filler is also provided.

Abstract: Methods and devices for preparing microscale polymer relief structures from a thin polymer layer on an absorbing substrate are described. The described methods are ultrafast (about 8 nanoseconds) and allow formation of patterned microstructures having complex morphologies and narrow line widths that are an order of magnitude smaller than the masks used in the methods.

Abstract: A method for repairing process-related damage of a dielectric film formed on a substrate caused by processing the dielectric film includes: irradiating the damaged dielectric film with UV light in an atmosphere of hydrocarbon-containing gas to restore the surface of the dielectric film; and irradiating the surface-restored dielectric film with UV light in an atmosphere of oxygen gas to partially remove the hydrocarbon film.

Abstract: Methods of fabricating coated components using multiple types of fillers are provided. One method comprises forming one or more grooves in an outer surface of a substrate. Each groove has a base and extends at least partially along the outer surface. A sacrificial filler is deposited within the groove, a second filler is deposited over the sacrificial filler, and a coating is disposed over at least a portion of the outer surface and over the second filler. The method further includes removing the sacrificial filler and at least partially removing the second filler from the groove(s), to define one or more channels for cooling the component.

Abstract: An electric field is formed between a material to be coated 18 and a coating sprayer 4 by applying a high voltage of ?1 kV to ?90 kV to an electrode needle 7 at a tip of the coating sprayer 4, while maintaining the material to be coated 18 positively. An inert gas is sprayed from an inert gas spraying nozzle 8 to the material to be coated 18, and a solution having a dielectric substance dissolved in a solvent is simultaneously sprayed from a dielectric solution spraying nozzle 6, while giving negative charge to the dielectric solution, to form a precursor polarization film. The solution is discharged from the spraying nozzle 6 by injecting the inert gas in the spraying nozzle 6. Then, the electric field is formed again and the precursor polarization film is further polarized, to thereby form a piezoelectric/pyroelectric film on the material to be coated 18.

Abstract: A method for forming a metal film with twins is disclosed. The method includes: (a) forming a metal film over a substrate, the metal film being made of a material having one of a face-centered cubic crystal structure and a hexagonal close-packed crystal structure; and (b) ion bombarding the metal film at a film temperature lower than ?20° C. in a vacuum chamber and with an ion-bombarding energy sufficient to cause plastic deformation of the metal film to generate deformation twins in the metal film.

Abstract: A process of manufacturing the main body of a bike helmet includes the following steps: (I.) coating with a base layer resin: that is, uniformly coating the entire shock absorbing liner with a base layer resin; (II.) coating with a protective layer resin: uniformly coating the base layer resin with a protective layer resin to form a shell; (III.) transferring pattern: transferring the pattern to print on the shell; and (IV.) clear coating: spraying clear coating on the pattern. By the aforesaid steps of the process, the shock absorbing liner and the shell are able to join tightly, which solidifies the helmet for better durability, to prolong the years of use, to substantially lower the production cost, and to boost the yield rate.