A semiconductor structure includes a substrate, a sensing device disposed over the substrate and including a plurality of protruding members protruded from the sensing device; a sensing structure disposed adjacent to the sensing device and including a plurality of sensing electrodes protruded from the sensing structure towards the sensing device; and an actuating structure disposed adjacent to the sensing device and configured to provide an electrostatic force on the sensing device based on a feedback from the sensing structure. Further, a method of manufacturing the semiconductor structure is also disclosed.

The present disclosure includes apparatuses and methods related to freezing a sacrificial material in forming a semiconductor. In an example, a method may include solidifying, via freezing, a sacrificial material in an opening of a structure, wherein the sacrificial material has a freezing point below a boiling point of a solvent used in a wet clean operation and removing the sacrificial material via sublimation by exposing the sacrificial material to a particular temperature range.

Various embodiments of the present disclosure are directed towards a method for forming a microelectromechanical systems (MEMS) device. The method includes forming a filter stack over a carrier substrate. The filter stack comprises a particle filter layer having a particle filter. A support structure layer is formed over the filter stack. The support structure layer is patterned to define a support structure in the support structure layer such that the support structure has one or more segments. The support structure is bonded to a MEMS structure.

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.

Various embodiments of the present disclosure are directed towards a microphone including a support structure layer disposed between a particle filter and a microelectromechanical systems (MEMS) structure. A carrier substrate is disposed below the particle filter and has opposing sidewalls that define a carrier substrate opening. The MEMS structure overlies the carrier substrate and includes a diaphragm having opposing sidewalls that define a diaphragm opening overlying the carrier substrate opening. The particle filter is disposed between the carrier substrate and the MEMS structure. A plurality of filter openings extend through the particle filter. The support structure layer includes a support structure having one or more segments spaced laterally between the opposing sidewalls of the carrier substrate. The one or more segments of the support structure are spaced laterally between the plurality of filter openings.

The present disclosure includes apparatuses and methods related to freezing a sacrificial material in forming a semiconductor. In an example, a method may include solidifying, via freezing, a sacrificial material in an opening of a structure, wherein the sacrificial material has a freezing point below a boiling point of a solvent used in a wet clean operation and removing the sacrificial material via sublimation by exposing the sacrificial material to a particular temperature range.

Various embodiments of the present disclosure are directed towards a microphone including a support structure layer disposed between a particle filter and a microelectromechanical systems (MEMS) structure. A carrier substrate is disposed below the particle filter and has opposing sidewalls that define a carrier substrate opening. The MEMS structure overlies the carrier substrate and includes a diaphragm having opposing sidewalls that define a diaphragm opening overlying the carrier substrate opening. The particle filter is disposed between the carrier substrate and the MEMS structure. A plurality of filter openings extend through the particle filter. The support structure layer includes a support structure having one or more segments spaced laterally between the opposing sidewalls of the carrier substrate. The one or more segments of the support structure are spaced laterally between the plurality of filter openings.

Provided is a method including at least the thermal treatment step of thermally treating a SOI substrate having a first silicon layer at a first temperature that the diffusion flow rate of an interstitial silicon atom in a silicon single crystal is higher than the diffusion flow rate of an interstitial oxygen atom and the processing step of processing the SOI substrate after the thermal treatment step to obtain a displacement enlarging mechanism.

Micro-Electro-Mechanical System (MEMS) structures, methods of manufacture and design structures are disclosed. The method includes forming at least one Micro-Electro-Mechanical System (MEMS) cavity. The method for forming the cavity further includes forming at least one first vent hole of a first dimension which is sized to avoid or minimize material deposition on a beam structure during sealing processes. The method for forming the cavity further includes forming at least one second vent hole of a second dimension, larger than the first dimension.

A method for manufacturing a MEMS device is disclosed. Moreover a MEMS device and a module including a MEMS device are disclosed. An embodiment includes a method for manufacturing MEMS devices includes forming a MEMS stack over a first main surface of a substrate, forming a polymer layer over a second main surface of the substrate and forming a first opening in the polymer layer and the substrate such that the first opening abuts the MEMS stack.