The present disclosure relates to a MEMS apparatus with a patterned anti-stiction layer, and an associated method of formation. The MEMS apparatus has a handle substrate defining a first bonding face and a MEMS substrate having a MEMS device and defining a second bonding face. The handle substrate is bonded to the MEMS substrate through a bonding interface with the first bonding face toward the second bonding face. An anti-stiction layer is arranged between the first and the second bonding faces without residing over the bonding interface.

The present disclosure, in some embodiments, relates to a method for manufacturing a MEMS apparatus. The method may be performed by forming an anti-stiction layer on one or more respective surfaces of a handle substrate and a MEMS substrate. The anti-stiction layer is patterned, therein defining a patterned anti-stiction layer that uncovers one or more predetermined locations associated with a bonding of the handle substrate to the MEMS substrate. The handle substrate is bonded to the MEMS substrate at the one or more predetermined locations.

The present disclosure relates to a microelectromechanical systems (MEMS) package featuring a flat plate having a raised edge around its perimeter serving as an anti-stiction device, and an associated method of formation. A CMOS IC is provided having a dielectric structure surrounding a plurality of conductive interconnect layers disposed over a CMOS substrate. A MEMS IC is bonded to the dielectric structure such that it forms a cavity with a lowered central portion the dielectric structure, and the MEMS IC includes a movable mass that is arranged within the cavity. The CMOS IC includes an anti-stiction plate disposed under the movable mass. The anti-stiction plate is made of a conductive material and has a raised edge surrounding at least a part of a perimeter of a substantially planar upper surface.

The present disclosure relates to a microelectromechanical systems (MEMS) package featuring a flat plate having a raised edge around its perimeter serving as an anti-stiction device, and an associated method of formation. A CMOS IC is provided having a dielectric structure surrounding a plurality of conductive interconnect layers disposed over a CMOS substrate. A MEMS IC is bonded to the dielectric structure such that it forms a cavity with a lowered central portion the dielectric structure, and the MEMS IC includes a movable mass that is arranged within the cavity. The CMOS IC includes an anti-stiction plate disposed under the movable mass. The anti-stiction plate is made of a conductive material and has a raised edge surrounding at least a part of a perimeter of a substantially planar upper surface.

A system including two components intended to be in friction contact with each other in a given direction, wherein the friction occurs in a functional area, wherein the system is at least one of the two components including, on a surface in the functional area, a texture formed of a series of troughs of rounded shape separated by peaks or a series of bumps of rounded shape separated by troughs, the troughs extending parallel in the given direction and allowing for the evacuation of debris produced by friction and serving as a reservoir for a lubricant. A method for manufacturing at least one component or a mold by the DRIE (deep reactive ion etching) process, wherein surface defects on the sidewalls machined by the DRIE process are used to form the troughs.

The present disclosure, in some embodiments, relates to a method for manufacturing a MEMS apparatus. The method may be performed by forming an anti-stiction layer on one or more respective surfaces of a handle substrate and a MEMS substrate. The anti-stiction layer is patterned, therein defining a patterned anti-stiction layer that uncovers one or more predetermined locations associated with a bonding of the handle substrate to the MEMS substrate. The handle substrate is bonded to the MEMS substrate at the one or more predetermined locations.

A microelectromechanical systems (MEMS) package with roughness for high quality anti-stiction is provided. A device substrate is arranged over a support device. The device substrate comprises a movable element with a lower surface that is rough and that is arranged within a cavity. A dielectric layer is arranged between the support device and the device substrate. The dielectric layer laterally encloses the cavity. An anti-stiction layer lines the lower surface of the movable element. A method for manufacturing the MEMS package is also provided.

A MEMS microphone includes a substrate defining a cavity, a diaphragm being spaced apart from the substrate, covering the cavity, and configured to generate a displacement of the diaphragm in response to an applied acoustic pressure, an anchor extending from an end portion of the diaphragm, and fixed to an upper surface of the substrate to support the diaphragm and a back plate disposed over the diaphragm, the back plate being spaced apart from the diaphragm such that an air gap is maintained between the back plate and the diaphragm, and defining a plurality of acoustic holes, wherein the anchor has a repetitive concave-convex shape in a direction toward a center of the diaphragm so that the anchor acts as a resistance to an acoustic wave.

A modification to rough polysilicon using ion implantation and silicide is provided herein. A method can comprise depositing a hard mask on a single crystal silicon, patterning the hard mask, and depositing metal on the single crystal silicon. The method also can comprise forming silicide based on causing the metal to react with exposed silicon of the single crystal silicon. Further, the method can comprise removing unreacted metal and stripping the hard mask from the single crystal silicon. Another method can comprise forming a MEMS layer based on fusion bonding a handle MEMS with a device layer. The method also can comprise implanting rough polysilicon on the device layer. Implanting the rough polysilicon can comprise performing ion implantation of the rough polysilicon. Further, the method can comprise performing high temperature annealing. The high temperature can comprise a temperature in a range between around 700 and 1100 degrees Celsius.

The application describes a MEMS transducer comprising a substrate having a cavity. The transducer exhibits a membrane layer supported relative to the substrate to define a flexible membrane. An upper surface of the substrate comprises an overlap region between the edge of the cavity and a perimeter of the flexible membrane where the membrane overlies the upper surface of the substrate. At least one portion of the overlap region of the upper surface of the substrate is provided with a plurality of recesses. The recesses are defined so as to extend from the edge of the cavity towards the perimeter of the flexible membrane.