Methods for producing a cohesive laser bond connection, wherein, in a first method step, a bond element (2) made from copper is provided, in a second method step, a contact element (3) made from copper is provided, and, in a third method step, the bond element (2) and the contact element (3) are connected to one another in a joined fashion under the action of green laser radiation (1).

A manufacturing method enabling the obtainment of a functional part essentially formed in a metallic material, all or part of the functional part delimiting a filtering medium permeable to a fluid and delimiting first and second main faces for a preferred circulation of the gas through the filtering medium. The method includes a main phase consisting of an additive manufacturing method in successive passes from a support tray. Each pass includes the deposition of at least one layer of the metallic material, the deposited material adhering to the metallic material deposited before. The deposition is controlled at each pass so the stack of metallic material constitutes the functional part. The filtering medium includes a coalescent network of connecting strands interconnected according to a three-dimensional spatial distribution between the faces, the connecting strands of the network delimiting therebetween pores spatially distributed within the filtering medium in three dimensions between the faces.

A method of laser processing of a metallic material is described. Furthermore, disclosed herein are aspects of a machine for laser processing of a metallic material arranged to implement the laser processing method, and a computer program comprising one or more code modules for implementing the aforementioned method when the program is executed by electronic processing means.

A laser processing system and a laser processing method that reduce irregularities on a cutting surface caused by a variation in a heat affected zone or a difference in the heat affected zone due to processing by a laser beam. The laser processing system is provided with: a laser processing device that scans a composite material containing reinforced fibers and a resin with a laser beam to process the composite material; and a control device that controls the laser processing device. The control device calculates a scanning angle formed by a fiber direction that is a direction of the reinforced fibers and a scanning direction that is a direction in which the laser beam is caused to scan, calculates a scanning condition of the laser beam on the basis of the calculated scanning angle, and controls scanning of the laser beam on the basis of the calculated scanning condition.

A substrate processing system includes a laser processing apparatus including a holder and a radiation unit, the holder being configured to hold a substrate including a base substrate, an irregularity pattern formed on a main surface of the base substrate, and an irregularity layer formed along the irregularity pattern, the radiation unit being configured to radiate a laser beam to a protrusion of the irregularity layer to flatten the irregularity layer by removing the protrusion in a state that the substrate is held by the holder; a controller configured to control a position of an irradiation point of the laser beam; and a polishing apparatus configured to polish the irregularity layer in which the protrusion is removed with the laser beam to be flattened.

A method of manufacturing a deposition mask includes: a splitting process in which a laser beam irradiated from a light source is split into a plurality of laser beams; a scanning process in which the plurality of laser beams are simultaneously scanned onto the mask substrate; and a tuning process in which irradiation states of the plurality of laser beams are finely changed to correspond to shapes of the plurality of pattern holes while the plurality of laser beams are scanned.

The invention provides a method of manufacturing a display panel and the display panel. The display panel is applied to a display device having a camera, and the display panel includes an alignment film layer, a liquid crystal layer, and a camera hole. The method includes: performing laser treatment to the alignment film layer to obtain a first light transmission hole and performing laser treatment to the liquid crystal layer to obtain a second light transmission hole. The method provided by the invention reduces a difference of amount of ambient light entering at different angles of the alignment film layer and the liquid crystal layer, and thereby improves imaging quality of the camera.

An optical fiber device may include an optical waveguide to guide a laser output from a first end of the optical waveguide to a second end of the optical waveguide. The optical fiber device may include a fiber telescope optically coupled to the second end of the optical waveguide to modify the laser output. The fiber telescope may include a first graded-index optical element, a first facet of the first graded-index optical element being fused to the second end of the optical waveguide; and a second graded-index optical element, a first facet of the second graded-index optical element being fused to a second facet of the first graded-index optical element.

Embodiments pertain to a system for controlling outputting of light towards objects, the system comprising a detection subsystem configured to detect, for at least one object, one or more values of object characteristics, the object characteristics comprising, at least, electromagnetic absorption characteristics, wherein detection of object characteristic values is performed such that the object remains structurally intact; a light source subsystem comprising at least one light source for generating output light and directing the output light towards an object; and a controller configured to control, based on the detected object characteristics values, at least one operational parameter value of the at least one light source such that at least some of the output light that is directed towards the object has electromagnetic characteristics that correspond to the detected values of the electromagnetic absorption characteristics of the object, in order to structurally change at least part of the respective object.

A reflow melting system for reflow melting a metal coating on an electrical contact area of a terminal includes a laser head for emitting a laser light onto the metal coating on the terminal to heat and melt the metal coating. A remote control terminal is provided in communication with the laser head for adjusting at least one working parameter of the laser head for optimizing the melting effect of the metal coating.