A method for fabricating a MEMS device includes depositing and patterning a first sacrificial layer onto a silicon substrate, the first sacrificial layer being partially removed leaving a first remaining oxide. Further, the method includes depositing a conductive structure layer onto the silicon substrate, the conductive structure layer making physical contact with at least a portion of the silicon substrate. Further, a second sacrificial layer is formed on top of the conductive structure layer. Patterning and etching of the silicon substrate is performed stopping at the second sacrificial layer. Additionally, the MEMS substrate is bonded to a CMOS wafer, the CMOS wafer having formed thereupon a metal layer. An electrical connection is formed between the MEMS substrate and the metal layer.

A MEMS microphone includes a substrate having a cavity, a back plate disposed over the substrate, a diaphragm being disposed between the substrate and the back plate and being spaced apart from the substrate and the back plate and at least one anti-buckling portion provided between the substrate and the diaphragm. The diaphragm covers the cavity and the diaphragm senses an acoustic pressure to create a displacement. The anti-buckling portion is configured to temporarily support the diaphragm in case of a warpage of the diaphragm to prevent a buckling of the diaphragm. Thus, the MEMS microphone can prevent the diaphragm from generating a warpage by more than a predetermined degree, so that the diaphragm can have a tensile stress and the buckling phenomenon of the diaphragm can be prevented.

A MEMS microphone includes a substrate having a cavity, a back plate disposed over the substrate and having a plurality of acoustic holes, a diaphragm disposed over the substrate to cover the cavity, the diaphragm being disposed under the back plate to be spaced apart from the back plate, including venting holes communicating with the cavity, and sensing an acoustic pressure to create a displacement, a first insulation layer interposed between the substrate and the diaphragm to support the diaphragm, and the first insulation layer including an opening formed at a position corresponding to the cavity to expose the diaphragm, a second insulating layer formed over the substrate to cover an upper face of the back plate and an insulating interlayer formed between the first insulation layer and the second insulation layer, and the insulation interlayer being located outside the diaphragm and supporting the second insulation layer to make the back plate be spaced from the diaphragm. Thus, a process of manufacturing the MEMS microphone may be simplified.

A MEMS microphone includes a substrate having a cavity, a back plate disposed over the substrate and having a plurality of acoustic holes, a diaphragm disposed between the substrate and the back plate, and an anchor extending from a circumference of the diaphragm to be connected with an end portion of the diaphragm. The diaphragm is spaced apart from the substrate and the back plate to covers the cavity, and the diaphragm senses an acoustic pressure to generate a displacement. The anchor extends from a circumference of the diaphragm to be connected with an end portion of the diaphragm, and is connected with the substrate to support the diaphragm. Thus, the MEMS microphone can prevent a portion of an insulation layer located around the anchor from remaining and can prevent a buckling phenomenon of the diaphragm from occurring.

The present disclosure relates to the field of sensor manufacturing technology, particularly discloses a method for manufacturing a micro-sensor body, comprising the steps of S1: applying a wet colloidal material on a substrate to form a colloidal layer, and covering a layer of one-dimensional nanowire film on the surface of the colloidal layer to form a sensor embryo; S2: drying the colloidal layer of the sensor embryo to an extent that the colloidal layer cracks into a plurality of colloidal islands, a portion of the one-dimensional nanowire film contracting into a contraction diaphragm adhered to the surface of the colloidal islands while the other portion of the one-dimensional nanowire film being stretched into a connection structure connected between the adjacent contraction diaphragms. By the method for manufacturing a micro-sensor body of the present disclosure, the contraction diaphragms and connection structures formed by stretching the one-dimensional nanowire film are connected stably, which enhances the stability of the sensor devices; and the cracking manner renders it easy to obtain a large-scale of sensor bodies with connection structure arrays in stable suspension.

Embodiments relate to microelectromechanical systems (MEMS) and more particularly to membrane structures comprising pixels for use in, e.g., display devices. In embodiments, a membrane structure comprises a monocrystalline silicon membrane above a cavity formed over a silicon substrate. The membrane structure can comprise a light interference structure that, depending upon a variable distance between the membrane and the substrate, transmits or reflects different wavelengths of light. Related devices, systems and methods are also disclosed.

A device with an out-of-plane electrode includes a device layer positioned above a handle layer, a first electrode defined within the device layer, a cap layer having a first cap layer portion spaced apart from an upper surface of the device layer by a gap, and having an etch stop perimeter defining portion defining a lateral edge of the gap, and an out-of-plane electrode defined within the first cap layer portion by a spacer.

A semiconductor structure is provided. The semiconductor structure includes a substrate, a plurality of vias, a signal transmitting portion, a heater and a sensing material. The plurality of vias penetrates the substrate, wherein each of the plurality of vias includes a conductive or semiconductive portion surrounded by an oxide layer. The signal transmitting portion is disposed in the substrate, wherein adjacent vias of the plurality of vias surrounds the signal transmitting portion. The heater is electrically connected to the signal transmitting portion, and the sensing material is disposed over the heater and electrically connected to the substrate. A method of manufacturing a semiconductor structure is also provided.

An antenna having radio-frequency (RF) resonators and methods for fabricating the same are described. In one embodiment, the antenna comprises a physical antenna aperture having an array of antenna elements, where the array of antenna elements includes a plurality of radio-frequency (RF) resonators, with each RF resonator of the plurality of RF resonators having an RF radiating element with a microelectromchanical systems (MEMS) device.

According to one embodiment, a strain and pressure sensing device includes a semiconductor circuit unit and a sensing unit. The semiconductor circuit unit includes a semiconductor substrate and a transistor. The transistor is provided on a semiconductor substrate. The sensing unit is provided on the semiconductor circuit unit, and has space and non-space portions. The non-space portion is juxtaposed with the space portion. The sensing unit further includes a movable beam, a strain sensing element unit, and first and second buried interconnects. The movable beam has fixed and movable portions, and includes first and second interconnect layers. The fixed portion is fixed to the non-space portion. The movable portion is separated from the transistor and extends from the fixed portion into the space portion. The strain sensing element unit is fixed to the movable portion. The first and second buried interconnects are provided in the non-space portion.