Abstract: An encapsulated MEMS process including a high-temperature anti-stiction coating that is stable under processing steps at temperatures over 450 C is described. The coating is applied after device release but before sealing vents in the encapsulation layer. Alternatively, an anti-stiction coating may be applied to released devices directly before encapsulation.

Abstract: A capping technology is provided in which, despite the fact that structures which are surrounded by a silicon-germanium filling layer are exposed using ClF3 etching through micropores in the silicon cap, an etching attack on the silicon cap is prevented, namely, either by particularly selective (approximately 10,000:1 or higher) adjustment of the etching process itself, or by using the finding that the oxide of a germanium-rich layer, in contrast to oxidized porous silicon, is not stable but instead may be easily dissolved, to protect the silicon cap.

Abstract: A method for producing a component, and a component, in particular a micromechanical and/or microfluidic and/or microelectronic component, is provided, the component including at least one patterned material region, and in a first step the patterned material region is produced in that microparticles of a first material are embedded in a matrix of a second material, and in a second step the patterned material region is rendered porous by etching using a dry etching method or a gas-phase etching method.

Abstract: A micromechanical component having a conductive substrate, an elastically deflectable diaphragm including at least one conductive layer, which is provided over a front side of the substrate, the conductive layer being electrically insulated from the substrate, a hollow space, which is provided between the substrate and the diaphragm and is filled with a medium, and a plurality of perforation openings, which run under the diaphragm through the substrate, the perforation openings providing access to the hollow space from a back surface of the substrate, so that a volume of the medium located in the hollow space may change when the diaphragm is deflected. Also described is a corresponding manufacturing method.

Abstract: A method for selective etching of an SiGe mixed semiconductor layer on a silicon semiconductor substrate by dry chemical etching of the SiGe mixed semiconductor layer with the aid of an etching gas selected from the group including ClF3 and/or ClF5, a gas selected from the group including Cl2 and/or HCl being added to the etching gas.

Abstract: A micromechanical component, having a substrate and a functional element, the functional element having a functional surface which has an anti-adhesion layer, that has been applied at least in regions, for reducing the surface adhesion forces, and in which the anti-adhesion layer is stable to a temperature of more than 800° C.

Abstract: A method for etching silicon carbide, a mask being produced on a silicon carbide layer, the unmasked areas of the silicon carbide layer being etched using a fluorine-containing compound, which is selected from the group including interhalogen compounds of fluorine and/or xenon difluoride. The use of chlorine trifluoride, chlorine pentafluoride, and/or xenon difluoride for structuring silicon carbide layers covered with masks containing silicon dioxide and/or silicon oxide carbide; a structured silicon carbide layer obtained by the method, and a microstructured electromechanical component or a microelectronic component including a structured silicon carbide layer obtained by the method.

Abstract: A capping technology is provided in which, despite the fact that structures which are surrounded by a silicon-germanium filling layer are exposed using ClF3 etching through micropores in the silicon cap, an etching attack on the silicon cap is prevented, namely, either by particularly selective (approximately 10,000:1 or higher) adjustment of the etching process itself, or by using the finding that the oxide of a germanium-rich layer, in contrast to oxidized porous silicon, is not stable but instead may be easily dissolved, to protect the silicon cap.

Abstract: An encapsulated MEMS process including a high-temperature anti-stiction coating that is stable under processing steps at temperatures over 450 C is described. The coating is applied after device release but before sealing vents in the encapsulation layer. Alternatively, an anti-stiction coating may be applied to released devices directly before encapsulation.

Abstract: An encapsulated MEMS process including a high-temperature anti-stiction coating that is stable under processing steps at temperatures over 450° C. is described. The coating is applied after device release but before sealing vents in the encapsulation layer. Alternatively, an anti-stiction coating may be applied to released devices directly before encapsulation.

Abstract: An encapsulated MEMS process including a high-temperature anti-stiction coating that is stable under processing steps at temperatures over 450 C is described. The coating is applied after device release but before sealing vents in the encapsulation layer. Alternatively, an anti-stiction coating may be applied to released devices directly before encapsulation.

Abstract: A micromechanical component having a conductive substrate, an elastically deflectable diaphragm including at least one conductive layer, which is provided over a front side of the substrate, the conductive layer being electrically insulated from the substrate, a hollow space, which is provided between the substrate and the diaphragm and is filled with a medium, and a plurality of perforation openings, which run under the diaphragm through the substrate, the perforation openings providing access to the hollow space from a back surface of the substrate, so that a volume of the medium located in the hollow space may change when the diaphragm is deflected. Also described is a corresponding manufacturing method.

Abstract: A method for etching a layer that is to be removed on a substrate, in which a Si1-xGex layer is the layer to be removed, this layer being removed, at least in areas, in gas phase etching with the aid of an etching gas, in particular ClF3. The etching behavior of the Si1-xGex layer can be controlled via the Ge portion in the Si1-xGex layer. The etching method is particularly well-suited for manufacturing self-supporting structures in a micromechanical sensor and for manufacturing such self-supporting structures in a closed hollow space, because the Si1-xGex layer, as a sacrificial layer or filling layer, is etched highly selectively relative to silicon.

Abstract: An encapsulated MEMS process including a high-temperature anti-stiction coating that is stable under processing steps at temperatures over 450° C. is described. The coating is applied after device release but before sealing vents in the encapsulation layer. Alternatively, an anti-stiction coating may be applied to released devices directly before encapsulation.

Abstract: An encapsulated MEMS process including a high-temperature anti-stiction coating that is stable under processing steps at temperatures over 450 C is described. The coating is applied after device release but before sealing vents in the encapsulation layer. Alternatively, an anti-stiction coating may be applied to released devices directly before encapsulation.