In an embodiment, a method for manufacturing a micro-electro-mechanical systems (MEMS) transducer device includes providing a substrate body with a surface, depositing an etch-stop layer (ESL) on the surface, depositing a sacrificial layer on the ESL, depositing a diaphragm layer on the sacrificial layer and removing the sacrificial layer, wherein depositing the sacrificial layer includes depositing a first sub-layer of a first material and depositing a second sub-layer of a second material, and wherein the first material and the second material are different materials.

The disclosure relates to a method for manufacturing a planarized etch-stop layer, ESL, for a hydrofluoric acid, HF, vapor phase etching process. The method includes providing a first planarized layer on top of a surface of a substrate, the first planarized layer having a patterned and structured metallic material and a filling material. The method further includes depositing on top of the first planarized layer the planarized ESL of an ESL material with low HF etch rate, wherein the planarized ESL has a low surface roughness and a thickness of less than 150 nm, in particular of less than 100 nm.

In an embodiment, an integrated MEMS transducer device includes a substrate body having a first electrode on a substrate, an etch stop layer located on a surface of the substrate, a suspended micro-electro-mechanical systems (MEMS) diaphragm with a second electrode, an anchor structure with anchors connecting the MEMS diaphragm to the substrate body and a sacrificial layer in between the anchors of the anchor structure, the sacrificial layer including a first sub-layer of a first material, wherein the first sub-layer is arranged on the etch stop layer, a second sub-layer of a second material, wherein the second sub-layer is arranged on the first sub-layer, and wherein the first and the second material are different materials.

The present disclosure is directed to a method for manufacturing a micro-electro-mechanical device. The method includes the steps of forming, on a substrate, a first protection layer of crystallized aluminum oxide, impermeable to HF; forming, on the first protection layer, a sacrificial layer of silicon oxide removable with HF; forming, on the sacrificial layer, a second protection layer of crystallized aluminum oxide; exposing a sacrificial portion of the sacrificial layer; forming, on the sacrificial portion, a first membrane layer of a porous material, permeable to HF; forming a cavity by removing the sacrificial portion through the first membrane layer; and sealing pores of the first membrane layer by forming a second membrane layer on the first membrane layer.

An integrated circuit (IC) device includes: a first substrate; a dielectric layer disposed over the first substrate; and a second substrate disposed over the dielectric layer. The second substrate includes anchor regions comprising silicon extending upwards from the dielectric layer, and a series of interdigitated fingers extend from inner sidewalls of the anchor regions. The interdigitated fingers extend generally in parallel with one another in a first direction and have respective finger lengths that extend generally in the first direction. A plurality of peaks comprising silicon is disposed on the dielectric layer directly below the respective interdigitated fingers. The series of interdigitated fingers are cantilevered over the plurality of peaks. A first peak is disposed below a base of a finger and has a first height, and a second peak is disposed below a tip of the finger and has a second height less than the first height.

The invention concerns the field of microelectronics and relates to a three-dimensional component which, for example as a sensor, measures the direction of a property in a vector field. The object of the present solution is to specify a three-dimensional component that is capable of measuring and/or generating vector fields in multiple directions and/or simultaneously with low space requirements. The object is attained with a three-dimensional component for the uni-, bi-, tri- or multi-directional measurement and/or generation of vector fields, in which component at least one element made of material systems in present on a three-dimensional carrier made of at least one carrier material, which element measures and/or generates at least one vector field in at least one direction in the spatial position of the element on, against and/or in the carrier.

The present disclosure is directed to a process for manufacturing a micro-electro-mechanical system (MEMS) device. The process includes, in part, forming a first sacrificial dielectric region on a semiconductor wafer; forming a structural layer of semiconductor material on the first sacrificial dielectric region; forming a plurality of first openings through the structural layer; forming a second sacrificial dielectric region on the structural layer; forming a ceiling layer of semiconductor material on the second sacrificial dielectric region; forming a plurality of second openings through the ceiling layer; forming on the ceiling layer a permeable layer; selectively removing the first and the second sacrificial dielectric regions; and forming on the permeable layer a sealing layer of semiconductor material.

A micromechanical sensor that is produced surface-micromechanically includes at least one mass element formed in a third functional layer that is non-perforated at least in certain portions. The sensor has a gap underneath the mass element that is formed by removal of a second functional layer and at least one oxide layer. The removal of the at least one oxide layer takes place by introducing a gaseous etching medium into a defined number of etching channels arranged substantially parallel to one another. The etching channels are configured to be connected to a vertical access channel in the third functional layer.

Embodiments relate to microelectromechanical systems (MEMS) and more particularly to membrane structures comprising pixels for use in, e.g., display devices. In embodiments, a membrane structure comprises a monocrystalline silicon membrane above a cavity formed over a silicon substrate. The membrane structure can comprise a light interference structure that, depending upon a variable distance between the membrane and the substrate, transmits or reflects different wavelengths of light. Related devices, systems and methods are also disclosed.

An electrooptical device includes a first metal layer disposed spaced apart from a first surface of a substrate and including a mirror, which modulates light, and a mirror support post, which has a tubular shape and protrudes from the mirror toward the substrate. The first metal layer is formed by forming a metal layer on a surface of a sacrificial layer having an opening, patterning the metal layer, and removing the sacrificial layer. Thus, the mirror support post is formed so as to extend over the inner wall of the opening. Here, the mirror support post has a thickness of not less than 1.5 times the length of the mirror support post.