A method of forming a semiconductor structure includes forming a substrate, forming an anchor layer, and forming one or more self-aligned nanotip pillar pairs disposed vertically between the substrate and the anchor layer. A given one of the nanotip pillar pairs comprises a bottom nanotip pillar and a top nanotip pillar, the bottom nanotip pillar comprising a base portion disposed on a top surface of the substrate and the top nanotip pillar comprising a base portion disposed in the anchor layer. The bottom nanotip pillar and the top nanotip pillar comprise sidewalls that taper to points as distance from the respective base portions increases.

The present invention provides an implantable microneedle and a manufacturing method therefor. An implantable microneedle according to the present invention comprises a coating layer for covering at least one part of the surface of a tip part of the microneedle. When exposed to moisture, the coating layer can be separated from the tip part of the microneedle and thus be implanted.

In an example, a wet cleaning process is performed to clean a structure having features and openings between the features while preventing drying of the structure. After performing the wet cleaning process, a polymer solution is deposited in the openings while continuing to prevent any drying of the structure. A sacrificial polymer material is formed in the openings from the polymer solution. The structure may be used in semiconductor devices, such as integrated circuits, memory devices, MEMS, among others.

An implantable microneedle and a manufacturing method therefor is disclosed. The implantable microneedle includes a coating layer for covering at least one part of the surface of a tip part of the microneedle. When exposed to moisture, the coating layer can be separated from the tip part of the microneedle and thus be implanted.

A semiconductor device is proposed. The semiconductor device comprises a membrane structure having an opening. Furthermore, the semiconductor device comprises a first backplate structure, which is arranged on a first side of the membrane structure, and a second backplate structure, which is arranged on a second side of the membrane structure. The semiconductor device furthermore comprises a vertical connection structure, which connects the first backplate structure to the second backplate structure. In this case, the vertical connection structure extends through the opening.

Disclosed herein is an antifouling device for large, nonplanar optical surfaces. The device can be used as marine or implantable applications that has nested multiscale features for active and passive anti-biofouling. By combining active and passive anti-biofouling mechanisms, this device will provide long-term protection against biofouling for over 10 years, extending the lifetime of self-clearing marine or implantable sensors.

A method of operating a mechanical switching device is disclosed. The switching device includes a housing, an assembly disposed in the housing, and a body. The assembly is thermally deformable and comprises a beam held in two different places by two arms secured to edges of the housing. The beam is remote from the body in a first configuration and in contact with and immobilized by the body in a second configuration. The assembly has the first configuration at a first temperature and the second configuration when one of the arms has a second temperature different from the first temperature. The method includes exposing an arm of the assembly to the second temperature, and releasing the beam using a release mechanism. The release mechanism includes a pointed element comprising a pointed region directed towards the body. The pointed element limits an open crater in a concave part of a projection.

Embodiments described herein include an antimicrobial substrate surface. An example embodiment includes a structure that includes an antimicrobial surface on a substrate. The antimicrobial surface includes a plurality of nanostructures. Each nanostructure includes a nanopillar on the substrate. The nanopillar has a height. Each nanostructure also includes a head covering a distal end and at least part of the height of the nanopillar.

A micro electro mechanical system (MEMS) microphone includes a first membrane, a second membrane, a third membrane disposed between the first membrane and the second membrane, a first cavity disposed between the first membrane and the third membrane and surrounded by a first wall, a second cavity disposed between the second membrane and the third membrane and surrounded by a second wall, and one or more first supports disposed in the first cavity and connecting the first membrane and the third membrane.

A MEMS device includes a membrane and a counter electrode structure spaced apart from the membrane. The counter electrode structure includes a non-planar conductive layer. The MEMS device includes an air gap between the membrane and the counter electrode structure. The air gap has a non-uniform thickness.