The present disclosure relates to an integrated chip including a semiconductor device substrate and a plurality of semiconductor devices arranged along the semiconductor device substrate. A micro-electromechanical system (MEMS) layer overlies the semiconductor device substrate. The MEMS layer includes a first moveable mass and a second moveable mass. A capping layer overlies the MEMS layer. The capping layer has a first lower surface directly over the first moveable mass and a second lower surface directly over the second moveable mass. An outgas layer is on the first lower surface and directly between the first pair of sidewalls. A lower surface of the outgas layer delimits a first cavity in which the first moveable mass is arranged. The second lower surface of the capping layer delimits a second cavity in which the second moveable mass is arranged.

3D nanochannel interleaved devices for molecular manipulation are provided. In one aspect, a method of forming a device includes: forming a pattern on a substrate of alternating mandrels and spacers alongside the mandrels; selectively removing the mandrels from a front portion of the pattern forming gaps between the spacers; selectively removing the spacers from a back portion of the pattern forming gaps between the mandrels; filling i) the gaps between the spacers with a conductor to form first electrodes and ii) the gaps between the mandrels with the conductor to form second electrodes; and etching the mandrels and the spacers in a central portion of the pattern to form a channel (e.g., a nanochannel) between the first electrodes and the second electrodes, wherein the first electrodes and the second electrodes are offset from one another across the channel, i.e., interleaved. A device formed by the method is also provided.

The present disclosure, in some embodiments, relates to a semiconductor structure. The semiconductor structure includes a substrate. As viewed from a top-view, the substrate has a first sidewall, one or more second sidewalls, and a plurality of third sidewalls. The first sidewall extends along a first direction and defines a first side of a trench. The one or more second sidewalls extends along the first direction and define a second side of the trench. The plurality of third sidewalls are oriented in parallel and extends in a second direction perpendicular to the first direction. The plurality of third sidewalls protrude outward from the second side of the trench and define a plurality of parallel releasing openings that are separated along the first direction by the substrate. The trench continuously extends in opposing directions past the plurality of parallel releasing openings.

The present disclosure, in some embodiments, relates to a method of semiconductor processing. The method may be performed by etching a substrate to define a trench within the substrate. A sacrificial material is formed within the trench. The sacrificial material has an exposed upper surface. A plurality of discontinuous openings are formed to expose separate segments of a sidewall of the sacrificial material. The plurality of discontinuous openings are separated by non-zero distances along a length of the trench. An etching process is performed to simultaneously etch the exposed upper surface and the sidewall of the sacrificial material.

A gyro sensor includes a plurality of beams connected via a turnaround part. A groove is provided on a main surface of at least one beam of the plurality of beams. Wall thicknesses on the main surface of two sidewalls facing each other of the groove in a direction orthogonal to a longitudinal direction of the beam satisfy 0.9≤T1/T2≤1.1, where T1 is the wall thickness of one sidewall and T2 is the wall thickness of the other sidewall.

At least some embodiments of the present disclosure relate to a semiconductor device package. The semiconductor device package includes a substrate with a first groove and a semiconductor device. The first groove has a first portion, a second portion, and a third portion, and the second portion is between the first portion and the third portion. The semiconductor device includes a membrane and is disposed on the second portion of the first groove. The semiconductor device has a first surface adjacent to the substrate and opposite to the membrane. The membrane is exposed by the first surface.

The present disclosure describes techniques for altering the epoxy wettability of a surface of a MEMS device. Particularly applicable to flip-chip bonding arrangements in which a top surface of a MEMS device is adhered to a package substrate. A barrier region is provided on a top surface of the MEMs device, laterally outside a region which forms, or overlies, the backplate and/or the cavity in the transducer substrate. The barrier region comprises a plurality of discontinuities, e.g. dimples, which inhibit the flow of epoxy.

A micromechanical sensor is described that includes: a substrate; a first functional layer that is situated on the substrate; a second functional layer that is situated on the first functional layer and that includes movable micromechanical structures; a cavity in the substrate that is situated below the movable mechanical structures; and a vertical trench structure that surrounds the movable micromechanical structures of the second functional layer and extends into the substrate down to the cavity.

A process for manufacturing a microelectromechanical device envisages: providing a wafer of semiconductor material; forming a buried cavity, completely contained within the wafer, and a structural layer formed by a surface portion of the wafer and suspended over the buried cavity; forming first trenches through the structural layer as far as the buried cavity, which define the suspended structure in the structural layer; filling the first trenches and the buried cavity with sacrificial material; forming a closing structure above the structural layer; removing the sacrificial material from the first trenches and from the buried cavity to release the suspended structure, the suspended structure being isolated and buried within the wafer in a buried environment formed by the first trenches and by the buried cavity.

A gyro sensor includes a plurality of beams connected via a turnaround part. A groove is provided on a main surface of at least one beam of the plurality of beams. Wall thicknesses on the main surface of two sidewalls facing each other of the groove in a direction orthogonal to a longitudinal direction of the beam satisfy 0.9T1/T21.1, where T1 is the wall thickness of one sidewall and T2 is the wall thickness of the other sidewall.