A housing for an electronic device is disclosed. A surface of the housing includes a laser-formed marking. The marking comprises a plurality of laser-formed pixels and may include a grayscale image. Electronic devices including the laser-marked housings and techniques for laser-marking the housings are also disclosed.

A housing for an electronic device is disclosed. A surface of the housing includes a laser-formed marking. The marking comprises a plurality of laser-formed pixels and may include a grayscale image. Electronic devices including the laser-marked housings and techniques for laser-marking the housings are also disclosed.

A laser device may include a first lens array including first lenses arranged in a first direction, a condenser lens disposed in a second direction intersecting the first direction of the first lens array and a first refractive index adjusting member disposed in a third direction opposite to the second direction of the first lens array.

A laser tool, in particular for the structuring of cylinder running surfaces, that offers the possibility of guiding the laser beam of the laser tool with high process reliability, it is provided that the laser tool has a laser source for producing laser beams that are passed through a lens tube located in a hollow shaft, wherein a lens through which the laser beams are passed is attached to the lens tube, wherein the hollow shaft is designed to be rotatable as a hollow-shaft motor, wherein a spindle, to which is attached an optical device for deflecting the laser beam onto a workpiece surface, is attached to the hollow shaft, wherein the hollow shaft is rotatable independently of the lens.

A laser tool, in particular for the structuring of cylinder running surfaces, that offers the possibility of guiding the laser beam of the laser tool with high process reliability, it is provided that the laser tool has a laser source for producing laser beams that are passed through a lens tube located in a hollow shaft, wherein a lens through which the laser beams are passed is attached to the lens tube, wherein the hollow shaft is designed to be rotatable as a hollow-shaft motor, wherein a spindle, to which is attached an optical device for deflecting the laser beam onto a workpiece surface, is attached to the hollow shaft, wherein the hollow shaft is rotatable independently of the lens.

Provided is a laser mark printing method and a method of producing a laser-marked silicon wafer that can reduce the machining strain left around dots constituting a laser mark. In a method of printing a laser mark having a plurality of dots on a silicon wafer, the plurality of dots are formed using laser light having a wavelength in the ultraviolet region.

Described are methods of treating surfaces of metal alloy substrates and associated metal alloy products. The methods may include providing an aluminum alloy product having a bulk and a surface and scanning abeam of high energy across the surface. The method may further include applying a liquid layer onto the surface prior to scanning a beam of high energy. The beam of high energy may interact with the surface and/or the liquid layer to form a treated surface. The beam of high energy may interact with the surface and/or the liquid layer to physically modify the at least a portion of the aluminum alloy product to form a treated sub-surface layer.

Described are methods of treating surfaces of metal alloy substrates and associated metal alloy products. The methods may include providing an aluminum alloy product having a bulk and a surface and scanning abeam of high energy across the surface. The method may further include applying a liquid layer onto the surface prior to scanning a beam of high energy. The beam of high energy may interact with the surface and/or the liquid layer to form a treated surface. The beam of high energy may interact with the surface and/or the liquid layer to physically modify the at least a portion of the aluminum alloy product to form a treated sub-surface layer.

An arrangement in which an angular prism is formed with two triangular part prisms which are connected to one another by a layer having properties splitting at least one laser beam into part beams. The two part prisms have two identical acute angles α. The laser beam is directed onto an outward-facing surface of one of the two part prisms. The at least one laser beam is split into two part beams by the reflection of a part of the radiation by the layer and transmission of a further part of the radiation through the layer. The part beams are each incident on an outward-facing surface, are reflected there and exit from the part prisms and are incident on at least one optical element and are aligned such that they interfere with one another in a region of a component in which a structural pattern is intended to be formed.

A method of making a fluid injection component for a gas turbine engine includes depositing material onto a piece of tube stock. The method includes machining an elbow into the deposited material, wherein machining the elbow includes forming a braze joint surface in the deposited material. Depositing can include laser cladding the material onto the piece of tube stock.