A biocompatible, implantable electrode for electrically active medical devices. The implantable medical electrode has a surface geometry which optimizes the electrical performance of the electrode, while mitigating the undesirable effects associated with prior art porous surfaces. The electrode has an optimized surface topography for improved electrical performance. Such a electrode is suitable for devices which may be permanently implanted in the human body as stimulation electrodes, such as pacemakers, or as sensors of medical conditions. Such is achieved by the application of ultrafast high energy pulses to the surface of a solid, monolithic electrode material for the purpose of increasing the surface area and thereby decreasing its after-potential polarization.

A firearm having a laser induced friction surface. A method for forming the laser induced friction surface on the firearm may includes the steps of disposing the laser machine adjacent to a component of the firearm, adjusting the laser machine, then applying the laser beam of the laser machine onto a component surface.

An electronic device includes a support member and a mount member mounting on the support member. The support member and the mount member are sealed by a resin member. The support member includes a surface having a laser irradiation mark. The mount member includes a surface having a rough portion with an accumulation of material of the support member.

A welding method according to an embodiment includes a preparation process and a welding process. A first welding material and a second welding material are prepared in the preparation process. The first welding material and the second welding material are welded in the welding process by irradiating a laser beam on at least one of the first welding material or the second welding material. At least one of the first welding material or the second welding material includes a first portion and a second portion. A laser absorptance of the second portion is higher than a laser absorptance of the first portion. The first welding material and the second welding material are welded in the welding process by irradiating the laser beam on the second portion.

The system may include a rotatable stage configured to support a ceramic substrate and an energy emitter positioned adjacent to the ceramic substrate. In some cases, the energy emitter may be configured to transmit an energy beam toward one or more outer faces of the ceramic substrate so as to modify a surface roughness of the one or more outer faces. In some cases, the method may include identifying a target surface roughness based at least in part on a target friction coefficient, and identifying a target surface area of the ceramic substrate, transmitting an energy beam toward the surface of the ceramic substrate via an energy emitter positioned adjacent to the ceramic substrate, and heating the target surface area of the surface of the ceramic substrate until a surface roughness of the target surface area is within a predetermined range of the target surface roughness.

A pulley assembly having a body, a shaft mount and a plurality of bolts is disclosed. The body is aligned to the shaft mount by providing a tight tolerance between a shoulder portion of the bolt and a neck portion of a counter sunk hole formed in the body. Additionally, an outer surface of the body may have a pattern of friction lines or patches formed by fusing particulate matter to the outer surface with heat generated by a laser beam.

Methods for processing a metal substrate for use in a power electronics device are provided. In one example, the method includes placing a metal substrate on a support associated with a laser system. The method includes performing a pulsed laser treatment process on at least a portion of the surface of the metal substrate. The pulsed laser treatment process exposes the at least a portion of the surface of the metal substrate to a plurality of laser pulses to modify a surface roughness of the at least a portion of the surface of the metal substrate. After performing the pulsed laser treatment process, the method includes creating a metallized interface for coupling an electrical component to the metal substrate at the at least a portion of the surface of the metal substrate.

A method for generating a structured surface on a substrate includes analyzing a substrate surface of the substrate and selecting, as a function of a condition of the substrate surface, method parameters including focus diameter, pulse peak power, pulse energy, point spacing, pulse length, pulse spacing and/or pulse sequence. The method further includes generating, by partial ablation and partial deposition via treatment with an intensive pulsed laser beam, surface structures having dimensions in the sub-micrometer range such that a multi-scale surface structure in the sub-micrometer and micrometer range adapted to intrinsically inhomogeneous properties of the substrate surface in the sub-micrometer range is generated. The substrate is an inhomogeneous substrate.

A method for roughening a surface of a body by a laser, the laser acting on the surface of a body and thereby creating recesses in the surface, and the laser thereby being directed and guided onto the surface and set in terms of its power output in such a way that recesses with at least two substantially different depths are created in the surface of the body.

The invention relates to a method of manufacturing a vibratable head (1) for an aerosol generator (2), the vibratable head (1) comprising a support member (4), a vibratable membrane (6) supported by the support member (4) and a vibrator (8) configured to vibrate the vibratable membrane (6). The method comprises the steps of providing the support member (4), roughening a surface portion (10) of the support member (4) by laser structuring, applying an adhesive (9) to at least a part of the roughened surface portion (10) of the support member (4) and attaching at least one element to the support member (4) by at least a portion of the adhesive (9). Further, the invention relates to a vibratable head (1) manufactured by this method, an aerosol generator (2) comprising such a vibratable head (1) and a method of manufacturing such an aerosol generator (2).