Abstract: The present invention relates to a method for producing a miniaturized separation column for chromatographic purposes including a porous stationary phase anchored in the column, including the following steps: (a) preparing a flat substrate of silicon, glass, glass ceramic or ceramic; (b) etching at least one channel structure into the flat substrate; (c) introducing a non-porous precursor material for the porous stationary phase into at least one portion of the channel structure (s); (d) forming a porous, three-dimensional network from the precursor material; and (e) fluid-tight covering of the channel structure(s) on the top side of the flat substrate.

Abstract: The invention relates to methods of producing a cap substrate, to methods of producing a packaged radiation-emitting device at the wafer level, and to a radiation-emitting device. By producing a cap substrate, providing a device substrate in the form of a wafer including a multitude of radiation-emitting devices, arranging the substrates one above the other such that the substrates are bonded along an intermediate bonding frame, and dicing the packaged radiation-emitting devices, improved packaged radiation-emitting devices are provided which are advantageously arranged within a cavity free from organics and can be examined, still at the wafer level, in terms of their functionalities in a simplified manner prior to being diced.

Abstract: The invention relates to an MEMS structure with a stack made of different layers and a spring-and-mass system varying in its thickness which is formed of the stack, and wherein, starting from a back side of the stack and the substrate, at laterally different positions, the substrate while leaving the first semiconductor layer, or the substrate, the first etch-stop layer and the first semiconductor layer are removed, and to a method for manufacturing such a structure.

Abstract: The invention is a method for structuring a flat substrate composed of glass material in the course of a viscous flow process. The glass flat substrate is joined to a surface of a flat substrate, which is preferably a semiconductor flat substrate, having at least one depression bounded by a circumferential edge located in the surface. In the course of a subsequent tempering process, glass material is changed to a viscous free-flowing state in which at least proportions of the free-flowing glass material of the flat substrate flow over the circumferential edge into the depression in the flat substrate.

Abstract: Embodiments of the present invention provide an apparatus including a micromirror, an excitation structure containing or supporting the micromirror, and at least one piezoelectric sensor. The excitation structure includes at least one piezoelectric actuator, the excitation structure being configured to resonantly excite the micromirror so as to cause a deflection of the micromirror. The at least one piezoelectric sensor is configured to provide a sensor signal dependent on the deflection of the micromirror, the piezoelectric sensor being connected to the excitation structure so that during the resonant excitation of the micromirror, the sensor signal and the deflection of the micromirror exhibit a fixed mutual phase relationship.

Abstract: A micromirror system that includes a chip frame, at least one spring element, and at least one mirror plate oscillatorily suspended in the chip frame via the at least one spring element. The chip frame and the at least one spring element include at least one microchannel which is provided with an inlet opening and an outlet opening for leading through a flowing coolant.

Abstract: The method according to the invention is used for producing optical components, in particular covers for encapsulating micro-systems, wherein at least one reinforcing element, which is produced before being arranged, is arranged on a first substrate, as a result of which a stack is produced. This stack is heated after being connected to a second substrate, as a result of which the first substrate is deformed such that at least one region, covered by the reinforcing element, of the first substrate is moved and/or is inclined or the first substrate is brought into contact with the reinforcing element. In an alternative method according to the invention, the reinforcing element is arranged on the second substrate, wherein this stack is then connected to the first substrate. The first substrate is subsequently heated and deformed such that a region of the first substrate is brought into contact with the reinforcing element.

Abstract: The invention relates to an MEMS structure with a stack made of different layers and a spring-and-mass system varying in its thickness which is formed of the stack, and wherein, starting from a back side of the stack and the substrate, at laterally different positions, the substrate while leaving the first semiconductor layer, or the substrate, the first etch-stop layer and the first semiconductor layer are removed, and to a method for manufacturing such a structure.

Abstract: The underlying invention presents a device which connects a vibratably suspended optical element to at least two actuators mounted fixedly on one side via curved spring elements, wherein the actuators are implemented to cause the vibratably suspended optical element to vibrate via the curved spring elements. Both the actuators and the entire system may be implemented to be more robust and be operated more reliably due to the curved shaping of the spring elements.

Abstract: The invention is a method for structuring a flat substrate composed of glass material in the course of a viscous flow process. The glass flat substrate is joined to a surface of a flat substrate, which is preferably a semiconductor flat substrate, having at least one depression bounded by a circumferential edge located in the surface. In the course of a subsequent tempering process, glass material is changed to a viscous free-flowing state in which at least proportions of the free-flowing glass material of the flat substrate flow over the circumferential edge into the depression in the flat substrate.

Abstract: Disclosed is a method of treating the surface of an electrically conducting substrate surface wherein a tool comprising an ion-conducting solid material is brought into contact at least in some areas with the substrate surface. The tool conducts the metal ions of the substrate and an electric potential is applied so that an electrical potential gradient is applied between the substrate surface and the tool in such a manner that metal ions are drawn from the substrate surface or deposited onto the substrate surface by means of the tool.

Abstract: The invention relates to a microsystem having at least one micromirror (1) and at least one micromirror actuator (2) for pivoting the at least one micromirror (1) about at least one axis from a relaxed resting position, comprising a frame chip and a transparent cover (3) disposed on the frame chip, wherein the frame chip has a chip frame (10), on which the at least one micromirror (1) is articulated in an elastically pivoting manner, wherein the at least one micromirror (1) is further disposed within the chip frame (10) and in a cavity (11) that is formed between the transparent cover (3) and a carrier layer.

Abstract: The cover according to the invention serves to encapsulate microsystems, wherein the cover comprises or is made of one or more cover units, and at least one cover unit comprises at least one first recess caused by deformation and bounded at least partially by at least one optical window, the quadratic surface roughness thereof being less than or equal to 25 nm. The invention further relates to a method for producing optical components, wherein the method is particularly also suitable for producing a cover according to the invention allowing encapsulation at the wafer level.

Abstract: The present invention relates to a method for producing a miniaturized separation column for chromatographic purposes including a porous stationary phase anchored in the column, including the following steps: (a) preparing a fiat substrate of silicon, glass, glass ceramic or ceramic; (b) etching at least one channel structure into the fiat substrate; (c) introducing a non-porous precursor material for the porous stationary phase into at least one portion of the channel structure(s); (d) forming a porous, three-dimensional network from the precursor material; and (e) fluid-tight covering of the channel structure(s) on the top side of the flat substrate.

Abstract: A method and a device are disclosed for follow-up treatment of the contour of the surface of at least one optical lens, in particular a microlens which is made of glass or a glass-type material and which has a convex lens surface delimited by a circumferential line abutting on a plane section surrounding the circumferential line and which has a lens underside facing the convex lens surface. Along the circumferential line of the optical lens on the plane section is placed a device perfectly matching the circumferential line and at least laterally bordering the convex lens surface, the optical lens is heated to a temperature of at least the transformation temperature of glass or glass-type material, pressure equalization prevails between the convex lens surface and the lens underside, after a certain period of time, during which the optical lens undergoes the temperature treatment and subsequent cooling below the transformation temperature, the device is removed from the optical lens.

Abstract: The cover according to the invention serves to encapsulate microsystems, wherein the cover comprises or is made of one or more cover units, and at least one cover unit comprises at least one first recess caused by deformation and bounded at least partially by at least one optical window, the quadratic surface roughness thereof being less than or equal to 25 nm. The invention further relates to a method for producing optical components, wherein the method is particularly also suitable for producing a cover according to the invention allowing encapsulation at the wafer level.

Abstract: The invention relates to a microsystem having at least one micromirror (1) and at least one micromirror actuator (2) for pivoting the at least one micromirror (1) about at least one axis from a relaxed resting position, comprising a frame chip and a transparent cover (3) disposed on the frame chip, wherein the frame chip has a chip frame (10), on which the at least one micromirror (1) is articulated in an elastically pivoting manner, wherein the at least one micromirror (1) is further disposed within the chip frame (10) and in a cavity (11) that is formed between the transparent cover (3) and a carrier layer.

Abstract: A micromechanical apparatus includes a moving element which comprises a controllable heating apparatus for introduction of a defined amount of heat into the moving element, wherein the apparatus furthermore has a control unit which is designed to control the heating apparatus as a function of an instantaneous temperature and/or of an instantaneous amount of heat that is introduced. The apparatus can be designed to project electromagnetic radiation when the moving element is in the form of a beam deflection unit for deflection of radiation, which originates from a radiation source, onto a projection surface.

Abstract: Disclosed is a method for producing single microlenses or an arrays of microlenses composed of a glass-type material, in which method a first substrate is provided with a surface containing impressions over which a second substrate composed of a glass-type material is placed at least partially overlapping it and is joined therewith under vacuum conditions. The substrate composite is tempered in such a manner that the second substrate softens and flows into the impressions of the first substrate, thereby structuring the side of the second substrate facing away from the first substrate in order to form at least one microlens surface.

Abstract: Disclosed is a method for producing single microlenses or an arrays of microlenses composed of a glass-type material, in which method a first substrate is provided with a surface containing impressions over which a second substrate composed of a glass-type material is placed at least partially overlapping it and is joined therewith under vacuum conditions. The substrate composite is tempered in such a manner that the second substrate softens and flows into the impressions of the first substrate, thereby structuring the side of the second substrate facing away from the first substrate in order to form at least one microlens surface.