Abstract: The invention relates to a process for connecting glass substrates which allows glass substrates to be aligned in a site-specific manner and to subsequently be connected to one another, and to the site-specifically aligned and interconnected glass substrates. Generally, the process relates to connecting glass substrates to one another, optionally also without site-specific alignment. The interconnected glass substrates obtainable by processes according to the invention are characterized by a firm bond with one another, which is preferably formed by solidified glass solder that is in form-fitting engagement with the glass substrates. Therein, recesses, which are preformed in the glass substrate, with glass solder are used for aligning and optionally for connecting the glass substrates.

Abstract: A method for creating at least one recess, in particular an aperture, in a transparent or transmissive material, includes: selectively modifying the material along a beam axis by electromagnetic radiation; and creating the at least one recess by one or more etching steps, using different etching rates in a modified region and in non-modified regions. The electromagnetic radiation produces modifications having different characteristics in the material along the beam axis such that the etching process in the material is heterogeneous and the etching rates differ from one another in regions modified with different characteristics under unchanged etching conditions.

Abstract: The invention relates to a process for connecting glass substrates which allows glass substrates to be aligned in a site-specific manner and to subsequently be connected to one another, and to the site-specifically aligned and interconnected glass substrates. Generally, the process relates to connecting glass substrates to one another, optionally also without site-specific alignment. The interconnected glass substrates obtainable by processes according to the invention are characterized by a firm bond with one another, which is preferably formed by solidified glass solder that is in form-fitting engagement with the glass substrates. Therein, recesses, which are preformed in the glass substrate, with glass solder are used for aligning and optionally for connecting the glass substrates.

Abstract: An optical component, in particular a passive component, for optical waveguiding, includes: optical waveguides formed in a carrier substrate as a waveguide pattern. The optical waveguides are formed in the carrier substrate by recesses by cutting out the optical waveguide. In an embodiment, the optical waveguide is connected to the carrier substrate by web-shaped supporting structures.

Abstract: A method for producing a technical mask includes: providing a technical mask including at least one plate-shaped substrate, the plate-shaped substrate being transparent to at least one laser wavelength; and producing at least one opening in the mask by laser-induced deep etching. In an embodiment, an etching attack takes place at least temporarily on one side during laser-induced deep etching.

Abstract: A method for machining, in particular for cutting an, in particular, planar substrate by laser-induced deep etching includes: moving laser radiation along a machining line; directing individual pulses onto the planar substrate at a spatial laser pulse distance (d); and subsequently removing an anisotropic material by etching at an etching rate (r) and an etching duration (t). Machining parameters are set according to a condition: 1>d/(R*t)>10?5.

Abstract: An optical component, in particular a passive component, for optical waveguiding, includes: optical waveguides formed in a carrier substrate as a waveguide pattern. The optical waveguides are formed in the carrier substrate by recesses by cutting out the optical waveguide. In an embodiment, the optical waveguide is connected to the carrier substrate by web-shaped supporting structures.

Abstract: A method for machining, in particular for cutting an, in particular, planar substrate by laser-induced deep etching includes: moving laser radiation along a machining line; directing individual pulses onto the planar substrate at a spatial laser pulse distance (d); and subsequently removing an anisotropic material by etching at an etching rate (r) and an etching duration (t). Machining parameters are set according to a condition: 1>d/(R*t)>10?5.

Abstract: A method for producing a technical mask includes: providing a technical mask including at least one plate-shaped substrate, the plate-shaped substrate being transparent to at least one laser wavelength; and producing at least one opening in the mask by laser-induced deep etching. In an embodiment, an etching attack takes place at least temporarily on one side during laser-induced deep etching.

Abstract: A method for creating at least one recess, in particular an aperture, in a transparent or transmissive material, includes: selectively modifying the material along a beam axis by electromagnetic radiation; and creating the at least one recess by one or more etching steps, using different etching rates in a modified region and in non-modified regions. The electromagnetic radiation produces modifications having different characteristics in the material along the beam axis such that the etching process in the material is heterogeneous and the etching rates differ from one another in regions modified with different characteristics under unchanged etching conditions.

Abstract: A method for producing an electrically conductive structure, e.g., a conducting track, on a non-conductive substrate material, having an additive (1) having at least one metal compound. The substrate material may be irradiated using a laser to selectively activate the metal compounds, for example inorganic metal compounds, contained in the additive (1). The metal seeds formed by the activation are then metallized to create the electrically conductive structure on the substrate material. Because the additive (1) has a preferably full-surface coating before the additive is introduced into the substrate material, such that the additive (1) is reduced and the coating is oxidized by the laser activation, the reaction partners necessary for the required chemical reaction with the additive (1) are provided by the coating. Because of the thereby significantly reduced interaction with the substrate material, the limitation to certain plastics or plastic groups also is lifted.