A MEMS pressure sensor is provided having a membrane made with one of plurality of metal layers. A lid is positioned above the membrane and connected to a plurality of cavity walls at distal ends of the membrane. The lid includes an array of holes positioned on a region of the lid. A fixed metal electrode is positioned below the lid.

Devices and methods for controlling molecular transport are disclosed herein. The devices include a membrane having a plurality of nanochannels extending therethrough. The membrane has an inner electrically conductive layer and an outer dielectric layer. The outer dielectric layer creates an insulative barrier between the electrically conductive layer and the contents of the nanochannels. At least one electrical contact region is positioned on a surface of the membrane. The electrical contact region exposes the electrically conductive layer of the membrane for electrical coupling to external electronics. When the membrane is at a first voltage, molecules flow through the nanochannels at a first release rate. When the membrane is at a second voltage, charge accumulation within the nanochannels modulates the flow of molecules through the nanochannels to a second release rate that is different than the first release rate. Methods of fabricating devices for controlling molecular transport are also disclosed herein.

A method for manufacturing a microelectromechanical systems microphone comprises depositing a membrane on a first sacrificial layer on a substrate, releasing the membrane by removing the first sacrificial layer, depositing a resist layer on the membrane, and patterning the resist layer to expose the membrane, such that at least one section of resist layer remains at at least one edge of the membrane to form an anchor. A microphone manufactured by this method is also provided. There is also provided a method for manufacturing a microelectromechanical systems microphone comprising depositing a membrane on a first sacrificial layer deposited on a substrate, releasing the membrane by removing at least the first sacrificial layer, depositing a resist layer on membrane, patterning the resist layer to expose an edge of the membrane, and forming an anchor at the exposed edge of the membrane. A microphone manufactured by this method is also provided.

An optical system including a dual-layer microelectromechanical systems (MEMS) device, and methods of fabricating and operating the same are disclosed. Generally, the MEMS device includes a substrate having an upper surface; a top modulating layer including a number of light modulating micro-ribbons, each micro-ribbon supported above and separated from the upper surface of the substrate by spring structures in at least one lower actuating layer; and a mechanism for moving one or more of the micro-ribbons relative to the upper surface and/or each other. The spring structures are operable to enable the light modulating micro-ribbons to move continuously and vertically relative to the upper surface of the substrate while maintaining the micro-ribbons substantially parallel to one another and the upper surface of the substrate. The micro-ribbons can be reflective, transmissive, partially reflective/transmissive, and the device is operable to modulate a phase and/or amplitude of light incident thereon.

A method for manufacturing a component and a component are provided for sensing a molecule. The method includes controlling a temperature during a reaction of two gases that react to produce a crystalline film spanning at least a cross-sectional area of a nanoaperture defined by a substrate among an array of nanoapertures aligned with crater structures defined by the substrate. A unique chemical vapor deposition (CVD) method that introduces a first gas and a second gas allows for formation of the crystalline film. When used in a molecule sensor, the component enables a user to record double-stranded DNA (dsDNA) translocations at unprecedented high (e.g., 1 MHz) bandwidths. The method for manufacturing the component enables development of applications requiring single-layer membranes built at- scale and enables high throughput 2-dimensional (2D) nanofluidics and nanopore studies.

A microfluidic chip and a fabrication method of the microfluidic chip are provided. The microfluidic chip includes an array substrate, and a hydrophobic layer disposed on a side of the array substrate. The hydrophobic layer includes at least one through-hole, and a through-hole of the at least one through-hole penetrates through the hydrophobic layer along a direction perpendicular to a plane of the array substrate. The microfluidic chip also includes at least one hydrophilic structure. A hydrophilic structure of the at least one hydrophilic structure is disposed in the through-hole.

The present invention discloses a MEMS microphone, which includes a substrate with a back cavity, a connection part, and a capacitive system arranged in the connection part. The capacitive system includes a first electrode connected to the inner wall of connection part, and a second electrode disposed on the substrate near the first electrode and spaced from the first electrode. The second electrode has two shape separation gaps. The shape separation gap includes a splitting gap in the second electrode, and two end gaps. The second electrode is divided into an effective vibration area and an auxiliary area by adopting a cracking gap structure. While improving the sensitivity of the first electrode, the stress concentration point of the second electrode is directed to the edge of the second electrode, so as to disperse the stress under the action of loud pressure.

An electronic component comprises a substrate including a main surface on which a functional unit is formed and a cap layer defining a cavity enclosing and covering the functional unit. The cap layer is provided with holes communicating an inside of the cavity with an outside of the cavity. A resin layer covers the cap layer and the main surface and includes one or more bores and a solder layer having a thickness less than a thickness of the resin layer disposed within the one or more bores.

A method for producing a cavity in a substrate composed of hard brittle material is provided. A laser beam of an ultrashort pulse laser is directed a side surface of the substrate and is concentrated by a focusing optical unit to form an elongated focus in the substrate. Incident energy of the laser beam produces a filament-shaped flaw in a volume of the substrate. The filament-shaped flaw extends into the volume to a predetermined depth and does not pass through the substrate. To produce the filament-shaped flaw, the ultrashort pulse laser radiates in a pulse or a pulse packet having at least two successive laser pulses. After at least two filament-shaped flaws are introduced, the substrate is exposed to an etching medium which removes material of the substrate and widens the at least two filament-shaped flaws to form filaments. At least two filaments are connected to form a cavity.

A sensor device includes a substrate, a sensing layer formed over the substrate, and a cover layer at least partially covering the sensing layer and protecting the sensing layer. The cover layer is a porous material or has a plurality of openings.