A device includes a substrate having first and second layers and an insulator layer between the first and second layers. A microelectromechanical system (MEMS) structure is provide on a portion of the second layer. A trench is formed in the second layer and around at least a part of a periphery of the portion of the second layer. An undercut is formed in the insulator layer and adjacent to the portion of the second layer. The undercut separates the portion of the second layer from the first layer. First and second pinholes extend from a plane of the insulator layer and in the first layer. The first and second pinholes are in fluid communication with the undercut and the trench.

Various three-dimensional devices that can be formed within the bulk of a semiconductor by photo-controlled selective etching are described herein. With more particularity, semiconductor devices that incorporate three-dimensional electrical vias, waveguides, or fluidic channels that are disposed within a semiconductor are described herein. In an exemplary embodiment, a three-dimensional interposer chip includes an electrical via, a waveguide, and a fluidic channel, wherein the via, the waveguide, and the fluidic channel are disposed within the body of a semiconductor element rather than being deposited on a surface. The three-dimensional interposer is usable to make electrical, optical, or fluidic connections between two or more devices.

Gas sensor, comprising: a substrate of semiconductor material; a first working electrode on the substrate; a second working electrode on the substrate, at a distance from the first working electrode; an interconnection layer extending in electrical contact with the first and the second working electrode, configured to change its conductivity when reacting with gas species to be detected. The interconnection layer is of titanium oxide, has a porosity between 40% and 60% in volume and is formed by a plurality of meso-pores having at least one dimension in the range 6-30 nm connected to nano-pores having at least one respective dimension in the range 1-5 nm.

In an assembly between a MEMS and/or NEMS electromechanical component and a casing, the electromechanical component includes at least one suspended and movable structure which is provided with at least one fixing zone, on which a region for receiving the casing is fixed, the suspended structure being at least partially formed in a cover for protecting the component or in a layer which is different from the one in which a sensitive element of the component is formed.

A process for forming inkjet nozzle devices on a frontside surface of a wafer substrate. The process includes the steps of: (i) providing the wafer substrate having a plurality of etched holes defined in the frontside surface, each etched hole being filled with first and second polymers such that the second polymer is coplanar with the frontside surface; (ii) forming the inkjet nozzle devices on the frontside surface using MEMS fabrication steps; and (iii) removing the first and second polymers via oxidative ashing, wherein first and second polymers are different.

An electromechanical pressure sensor system, in particular microphone type, including an electromechanical transducer, signal processing device, a substrate for receiving at least one support of the electromechanical transducer and/or signal processing device, a protective cover arranged on the upper face of the substrate, the support of the electromechanical transducer and/or signal processing device being housed in at least one cavity located on the lower face of the substrate is disclosed.

A MEMS package includes a MEMS chip, a package substrate which the MEMS chip is adhered and a thin-film filter which is adhered to the package substrate or the MEMS chip. The thin-film filter includes a thin-film part having a film surface and a rear film surface arranged a rear side of the film surface, and a plurality of through holes being formed to penetrate the thin-film part from the film surface to the rear film surface. The through holes are formed in an adhesive region of the thin-film part. The adhesive region is adhered to the package substrate or the MEMS chip.

The present application teaches microphones and manufacturing methods therefor and relates to the field of semiconductor technologies. In some implementations, a method may include: providing a substrate structure, the substrate structure including a substrate and a first insulating layer covering a first part of the substrate; forming a first electrode plate layer, the first electrode plate layer covering a part of the first insulating layer; and forming a second insulating layer, the second insulating layer covering a part of a region of the first insulating layer which is not covered by the first electrode plate layer and a part of the first electrode plate layer, where when seen from the top, the first electrode plate layer and the second insulating layer form an angle, the angle exposes a second part of the substrate, and a degree of the angle is larger than or equal to 90 and is smaller than or equal to 180. The present application can improve a problem of unexpected holes formed in the microphone.

Provided are a MEMS microphone chip and an MEMS microphone. The MEMS microphone chip comprises a substrate, a backplate and a vibration diaphragm, the backplate and the vibration diaphragm constituting two electrodes of a capacitor respectively, the backplate and the vibration diaphragm being suspended above the substrate, the backplate being located between the substrate and the vibration diaphragm, and the substrate being provided with a back chamber and a support column, the support column being connected to a side wall of the back chamber via a connection portion, a through hole or a notch being formed in the connection portion through its thickness direction, to allow spaces at opposite sides of the connection portion to communicate with each other; and the support column being configured to support the backplate.

A structure forming method according to an aspect is a structure forming method for forming a first hole and a second hole having width smaller than width of the first hole in a substrate with dry etching and forming a structure. The structure forming method includes forming an etching mask on the substrate, etching a portion of the etching mask overlapping a first hole forming region where the first hole is formed, etching a portion of the etching mask overlapping a second hole forming region where the second hole is formed, and performing the dry etching of the substrate using the etching mask as a mask.