A MEMS infrared sensing device includes a substrate and an infrared sensing element. The infrared sensing element is provided above the substrate and has a sensing area and an infrared absorbing area which do not overlap each other. The infrared sensing element includes two infrared absorbing structures, an infrared sensing layer provided between the two infrared absorbing structures, and an interdigitated electrode structure located in the sensing area. Each of the two infrared absorbing structures includes at least one infrared absorbing layer, and the two infrared absorbing structures are located in the sensing area and the infrared absorbing area. The infrared sensing layer is located in the sensing area and does not extend into the infrared absorbing area. The interdigitated electrode structure is in electrical contact with the infrared sensing layer.

The application describes MEMS transducer having a flexible membrane and which seeks to alleviate and/or redistribute stresses within the membrane layer. A membrane having a first/active region and a second/inactive region is described.

A method of manufacturing a semiconductor structure includes following operations. A first substrate is provided. A plate is formed over the first substrate. The plate includes a first tensile member, a second tensile member, a semiconductive member between the first tensile member and the second tensile member, and a plurality of apertures penetrating the first tensile member, the semiconductive member and the second tensile member. A membrane is formed over and separated from the plate. The membrane include a plurality of holes. A plurality of conductive plugs passing through the plate or membrane are formed. A plurality of semiconductive pads are formed over the plurality of conductive plugs. The plate is bonded to a second substrate. The second substrate includes a plurality of bond pads, and the semiconductive pads are in contact with the bond pads.

Packaging of microfabricated devices, such as integrated circuits, microelectromechanical systems (MEMS), or sensor devices is described. The packaging is 3D heterogeneous packaging in at least some embodiments. The 3D heterogeneous packaging includes an interposer. The interposer includes stress relief platforms. Thus, stresses originating in the packaging do not propagate to the packaged device. A stress isolation platform is an example of a stress relief feature. A stress isolation platform includes a portion of an interposer coupled to the remainder of the interposer via stress isolation suspensions. Stress isolation suspensions can be formed by etching trenches through the interposer.

A transducer includes a first piezoelectric layer; and a second piezoelectric layer that is above the first piezoelectric layer; wherein the second piezoelectric layer is a more compressive layer with an average stress that is less than or more compressive than an average stress of the first piezoelectric layer.

A method for manufacturing a microelectromechanical systems (MEMS) microphone comprises depositing a membrane on a first sacrificial layer, wherein the first sacrificial layer is deposited on a substrate, etching the substrate to define a cavity, releasing the membrane by removing at least the first sacrificial layer, and forming at least one anchor at the edge of the membrane.

In one embodiment, a method of manufacturing a semiconductor device includes oxidizing a substrate to form local oxide regions that extend above a top surface of the substrate. A membrane layer is formed over the local oxide regions and the top surface of the substrate. A portion of the substrate under the membrane layer is removed. The local oxide regions under the membrane layer are removed.

The present disclosure relates integrated chip structure including a MEMS actuator. The MEMS actuator includes an anchor having a first plurality of branches extending outward from a central region of the anchor. The first plurality of branches respectively include a first plurality of fingers. A proof mass surrounds the anchor and includes a second plurality of branches extending inward from an interior sidewall of the proof mass. The second plurality of branches respectively include a second plurality of fingers interleaved with the first plurality of fingers as viewed in a top-view. One or more curved cantilevers are coupled between the proof mass and a frame wrapping around the proof mass. The one or more curved cantilevers have curved outer surfaces having one or more inflection points as viewed in the top-view.

A method for forming a microscale device may include growing, by a chemical vapor deposition, a patterned forest of vertically aligned carbon nanotubes, wherein the patterned forest defines a component of the microscale device, and applying a conformal non-metal coating to the vertically aligned carbon nanotubes throughout the patterned forest, wherein the conformal non-metal coating comprises a substantially uniform thickness along a length of the vertically aligned carbon nanotubes. The method may also include connecting adjacent vertically aligned carbon nanotubes together with the conformal non-metal coating without filling interstices between the adjacent vertically aligned carbon nanotubes, wherein the connecting of the vertically aligned carbon nanotubes is configured to increase a strength of the vertically aligned carbon nanotubes of the patterned forest above a threshold level to withstand forces applied during a wet etching process, and infiltrating the interstices between the adjacent vertically aligned carbon nanotubes with a metallic material.

A microelectromechanical systems device includes a vibrator and a reinforcing film. The vibrator includes a piezoelectric element configured to convert pressure to an electrical signal. The reinforcing film is configured to reinforce strength of the vibrator. The vibrator further has a groove at which a portion of the reinforcing film is disposed.