The invention relates to a method for producing a structure with spatial encoded functionality, the method comprising: providing in a volume (114) a first photosensitive material (116) that is two-photon crosslinking compatible, generating in the volume (114) a framework of crosslinked first photo-sensitive material (116), the generating of the framework comprising exposing the first photosensitive material (116) with a first focused laser beam (118) according to a first pattern for specifically initiating a two-photon crosslinking of the first photosensitive material (116) in accordance with the first pattern, removing from the volume (114) any remaining non-crosslinked portions of the first photosensitive material (116), providing to the volume (114) a second photosensitive material (116) that is two-photon crosslinking compatible, generating in the volume (114) the structure, the generating of the structure comprising exposing the second photosensitive material (116) with a second focused laser beam (118) according to a second pattern for specifically initiating a two-photon crosslinking of predefined surface portions of the framework and the second photosensitive material (116) in accordance with the second pattern, removing from the volume (114) any remaining non-crosslinked portions of the second photosensitive material (116).

Disclosed is an ultrasonic transducer that is provided with: a bottom electrode; an electric connection part which is connected to the bottom electrode from the bottom of the bottom electrode; a first insulating film which is formed so as to cover the bottom electrode; a cavity which is formed on the first insulating film so as to overlap the bottom electrode when seen from above; a second insulating film which is formed so as to cover the cavity; and a top electrode which is formed on the second insulating film so as to overlap the cavity when seen from above. The electric connection part to the bottom electrode is positioned so as to not overlap the cavity when seen from above.

A method for producing a plurality of sensor devices. The method includes: furnishing a substrate having contact points in a plurality of predetermined regions for sensor chips; disposing the sensor chips in the predetermined regions on the substrate, and electrically contacting the sensor chips to the contact points; attaching a frame structure with an adhesive material on the substrate and between the sensor chips, the frame structure proceeding laterally around the sensor chips, the frame structure extending, after attachment, vertically beyond the sensor chips and forming a respective cavity for at least one of the sensor chips, and a membrane spanning at least one of the cavities for the sensor chips so as to cover it; and singulating the substrate, or the frame structure and the substrate, around the respective cavities into several sensor devices.

In one embodiment of the present invention, an electronic device includes a first emitter/collector region and a second emitter/collector region disposed in a substrate. The first emitter/collector region has a first edge/tip, and the second emitter/collector region has a second edge/tip. A gap separates the first edge/tip from the second edge/tip. The first emitter/collector region, the second emitter/collector region, and the gap form a field emission device.

An apparatus includes a cavity within a substrate. A MEMS structure is within the cavity, wherein the cavity includes the MEMS structure. A trench is connected to the cavity, wherein the trench is not directly opposite the MEMS structure. An oxide layer lines the trench and the cavity. A seal layer seals the trench and traps a predetermined pressure within the cavity and the trench.

In one embodiment of the present invention, an electronic device includes a first emitter/collector region and a second emitter/collector region disposed in a substrate. The first emitter/collector region has a first edge/tip, and the second emitter/collector region has a second edge/tip. A gap separates the first edge/tip from the second edge/tip. The first emitter/collector region, the second emitter/collector region, and the gap form a field emission device.

The disclosure relates to a method of making a microstructure on a substrate. A carbon nanotube structure is provided, wherein the carbon nanotube structure includes a number of carbon nanotubes arranged orderly and defines a number of first openings. A carbon nanotube composite is formed by applying a protective layer on the carbon nanotube structure, wherein the carbon nanotube composite structure defines a number of second openings. The carbon nanotube composite structure is placed on a surface of the substrate, wherein parts of the surface are exposed from the number of second openings. The surface of the substrate is dry etched by using the carbon nanotube composite structure as a mask.

A large aperture CMUT transducer array is formed of a plurality of adjacently located tiles of CMUT cells. The adjacent edges of the tiles are formed by an anisotropic etch process, preferably a deep reactive ion etching process which is capable of cutting through the die and its substrate while maintaining vertical edges in close proximity to the CMUT cells at the edge of the tile. This enables the CMUT cells of continuous rows or columns to exhibit a constant pitch over multiple CMUT cell tiles. The tiles also contain interconnect electrodes along an edge for making electrical connections to the tiles with flex circuit.

A method of forming a semiconductor device comprises bonding a capping wafer and a base wafer to form a wafer package. The base wafer comprises a plurality of chip package portions. The capping wafer comprises a plurality of isolation trenches. Each isolation trench of the plurality of isolation trenches is configured to substantially align with a corresponding chip package portion of the plurality of chip package portions. The method also comprises separating the wafer package into a plurality of chip packages. Each chip package of the plurality of chip packages comprises at least one chip package portion of the plurality of chip package portions.

Methods, systems, computer-readable media, and apparatuses for high density Micro-Electro-Mechanical Systems (MEMS) are presented. In some embodiments, a method for manufacturing a micro-electro-mechanical device on a substrate can comprise etching a release via through a layer of the device. The method can further comprise creating a cavity in the layer of the device using the release via as a conduit to access the desired location of the cavity, the cavity enabling movement of a transducer of the device. The method can then comprise depositing low impedance, electrically conductive material into the release via to form an electrically conductive path through the layer. Finally, the method can comprise electrically coupling the electrically conductive material to an electrode of the transducer.