Abstract: A microsystem has a first cavity which is sealed off from the surroundings and a second cavity which is sealed off from the surroundings. The first cavity is bounded by a first bond joint and the second cavity is bounded by a second bond joint. Either the first bond joint or the second bond joint is a eutectic bond joint or a diffusion-soldered joint.

Abstract: A contact arrangement for establishing a spaced, electrically conducting connection between a first wafer and a second wafer includes an electrical connection contact, a passivation layer on the electrical connection contact, and a dielectric spacer layer arranged on the passivation layer, wherein the contact arrangement is arranged at least on one of the first wafer and the second wafer, wherein the contact arrangement comprises trenches at least partly filled with a first material capable of forming a metal-metal connection, wherein the trenches are continuous trenches from the dielectric spacer layer through the passivation layer as far as the electrical connection contact, and wherein the first material is arranged in the trenches from the electrical connection contact as far as the upper edge of the trenches.

Abstract: A micromechanical microphone device includes a membrane that is mounted in an elastically deflectable manner above a substrate and that has at least one gate electrode. The device further includes a source region and a drain region provided in or on the substrate with a channel region therebetween. The channel region is at least partly covered by the gate electrode and is spaced apart from the gate electrode by a gap. The membrane is deflectable under the influence of sound in such a way that the gap is variable.

Abstract: A manufacturing method for a micromechanical component having a thin-layer capping.

Abstract: A method for manufacturing a semiconductor structure is provided which includes the following steps: a crystalline semiconductor substrate (1) is supplied; a porous region (10) is provided adjacent to a surface (OF) of the semiconductor substrate (1); a dopant (12) is introduced into the porous region (10) from the surface (OF); and the porous region (10) is thermally recrystallized into a crystalline doping region (10?) of the semiconductor substrate (1) whose doping type and/or doping concentration and/or doping distribution are/is different from those or that of the semiconductor substrate (1). A corresponding semiconductor structure is likewise provided.

Abstract: A magnetometer is described, having a substrate and a magnetic core, the substrate having an excitation coil for generating a magnetic flux in the magnetic core; and the excitation coil having a coil cross section, which is aligned generally perpendicular to a main plane of extension of the substrate. The magnetic core is situated outside the coil cross section.

Abstract: A method for producing a micromechanical component is described. The method includes providing a substrate having a layer system including an insulating material situated on the substrate, a conductive layer section and a protective layer structure connected to the conductive layer section, which borders a section of the insulating material. The method furthermore includes carrying out an isotropic etching process for removing a part of the insulating material, the conductive layer section and the protective layer structure preventing the removal of the bordered section of the insulating material; and a structural element being developed, which includes the conductive layer section, the protective layer structure and the bordered section of the insulating material.

Abstract: A cost-effective technology for implementing a micromechanical component is provided, whose layer construction includes at least one diaphragm on the upper side and at least one counter-element, a hollow space being formed between the diaphragm and the counter-element, and the counter-element having at least one through hole to a back volume. This back volume is formed by a sealed additional hollow space underneath the counter-element and is connected to the upper-side of the layer construction by at least one pressure equalization opening. This component structure permits the integration of the micromechanical sensor functions and evaluation electronics on one chip and is additionally suitable for mass production.

Abstract: A method for manufacturing a capped sensor element by providing a substrate with a sensor structure, the sensor structure being produced in the substrate using a sacrificial material, applying a cap made of zeolite to the sensor structure and the sacrificial material, and removing the sacrificial material, the sacrificial material being removed through the cap made of zeolite. A sensor element having capping is also provided.

Abstract: A method for manufacturing a semiconductor structure is provided which includes the following operations: supplying a crystalline semiconductor substrate, providing a porous region adjacent to a surface of the semiconductor substrate, introducing a dopant into the porous region from the surface, and thermally recrystallizing the porous region into a crystalline doping region of the semiconductor substrate whose doping type and/or doping concentration and/or doping distribution are/is different from those or that of the semiconductor substrate. A corresponding semiconductor structure is likewise provided.

Abstract: A method for manufacturing porous microstructures in a silicon semiconductor substrate, porous microstructures manufactured according to this method, and the use thereof.

Abstract: An arrangement having a first and a second substrate is disclosed, wherein the two substrates are connected to one another by means of an SLID (Solid Liquid InterDiffusion) bond. The SLID bond exhibits a first metallic material and a second metallic material, wherein the SLID bond comprises the intermetallic Al/Sn-phase.

Abstract: A method for producing a micromechanical component, includes providing a first substrate, developing a micropattern on the first substrate, the micropattern having a movable functional element, providing a second substrate, and developing an electrode in the second substrate for the capacitive recording of a deflection of the functional element. The method further includes connecting the first and the second substrate, a closed cavity being formed which encloses the functional element, and the electrode bordering on the cavity in an area of the functional element.

Abstract: A micro-structured reference element for use in a sensor having a substrate and a dielectric membrane. The reference element has an electrical property which changes its value on the basis of temperature. The reference element is arranged with respect to the substrate so that the reference element is (i) electrically insulated from the substrate, and (ii) thermally coupled to the substrate. The reference element is arranged on the underside of the dielectric membrane. The reference element and side walls of the substrate define a circumferential cavern therebetween, which is also bounded by the dielectric membrane, arranged between them. The dielectric membrane is connected to the substrate. A surface area of the reference element which is covered by the dielectric membrane is greater than or equal to 10% and less than or equal to 100% of the possible coverable surface area.

Abstract: A sensor, in particular a thermal sensor and/or gas sensor, encompassing an electrical sensor component having an electrical property whose value changes in temperature-dependent fashion, wherein the temperature-dependent electrical property is a resistance or an impedance. Thermal and electrical decoupling of the active structure from the substrate is accomplished by way of porous silicon and/or a cavity manufactured by electropolishing.

Abstract: A manufacturing method for a porous microneedle array includes: forming a plurality of porous microneedle arrays, each having at least one microneedle and a porous carrier zone lying beneath it on the face of a semiconductor substrate; forming an interlayer between a non-porous residual layer of the semiconductor substrate located on the back side of the semiconductor substrate and the carrier zone, which has greater porosity than the carrier zone; detaching the residual layer from the carrier zone by breaking up the interlayer; and separating the microneedle arrays into corresponding chips.

Abstract: A micromechanical component having a substrate and having a thin-layer, as well as having a cavity which is bounded by the substrate and the thin-layer, at least one gas having an internal pressure being enclosed in the cavity. The gas phase has a non-atmospheric composition. A method for producing a micromechanical component having a substrate and having a thin-layer encapsulation, as well as having a cavity which is bounded by the substrate and the thin-layer encapsulation. The method has the steps of positioning a polymer in a cavity, closing the cavity and generating a gas phase of non-atmospheric composition in the cavity by decomposing at least a part of the polymer. An internal pressure is generated, which may be higher than the process pressure when the cavity is closed.

Abstract: An inertial sensor, having a field effect transistor which includes a gate electrode (9), a source electrode (3a?,3a?,3a??), a drain electrode (3b?,3b?,3b??) and a channel area (4) situated between the source electrode (3a?,3a?,3a??) and the drain electrode (3b?,3b?,3b??) and whose gate electrode (9) is situated at a distance above the channel area (4). The gate electrode (9) is designed and situated to be stationary and the channel area (4) is designed and situated to be movable. Furthermore, the present invention also relates to a method for manufacturing a motion sensor of this type.

Abstract: A sensor having a monolithically integrated structure for detecting thermal radiation includes: a carrier substrate, a cavity, and at least one sensor element for detecting thermal radiation. Incident thermal radiation strikes the sensor element via the carrier substrate. The sensor element is suspended in the cavity by a suspension.

Abstract: A microsystem, e.g., a micromechanical sensor, has a first cavity which is sealed off from the surroundings and a second cavity which is sealed off from the surroundings. The first cavity is bounded by a first bond joint and the second cavity is bounded by a second bond joint. Either the first bond joint or the second bond joint is a eutectic bond joint or a diffusion-soldered joint.