A semiconductor oxide plate is formed on a recessed surface in a semiconductor matrix material layer. Comb structures are formed in the semiconductor matrix material layer. The comb structures include a pair of inner comb structures spaced apart by a first semiconductor portion. A second semiconductor portion that laterally surrounds the first semiconductor portion is removed selective to the comb structures using an isotropic etch process. The first semiconductor portion is protected from an etchant of the isotropic etch process by the semiconductor oxide plate, the pair of inner comb structures, and a patterned etch mask layer that covers the comb structures. A movable structure for a MEMS device is formed, which includes a combination of the first portion of the semiconductor matrix material layer and the pair of inner comb structures.

The present invention is characterized by involving a light source irradiating the inside of an ion source with light, a camera acquiring intensity as information of scattered light by droplets generated by electrospraying, and a processing device storing, in a storage unit, determination reference information indicating a relationship between a parameter of a channel system of a liquid chromatography device and the intensity, in which the processing device executes: acquiring the intensity from the camera; comparing the acquired intensity with the determination reference information; and determining a failure of a channel system in the liquid chromatography device by detecting a change in the scattered light relative to a value of the determination reference information based on the acquired intensity by comparing the acquired intensity with the determination reference information.

The present disclosure relates to an integrated chip structure. The integrated chip structure includes a MEMS (microelectromechanical systems) actuator. The MEMS actuator has an anchor. A proof mass continuously wraps around the anchor in a closed loop. One or more curved cantilevers are coupled between the proof mass and a frame. The frame wraps around the proof mass. The one or more curved cantilevers include curved outer surfaces arranged directly between a sidewall of the frame and a sidewall of the proof mass, as viewed in a top-view.

Gas sensor, comprising: a substrate of semiconductor material; a first working electrode on the substrate; a second working electrode on the substrate, at a distance from the first working electrode; an interconnection layer extending in electrical contact with the first and the second working electrode, configured to change its conductivity when reacting with gas species to be detected. The interconnection layer is of titanium oxide, has a porosity between 40% and 60% in volume and is formed by a plurality of meso-pores having at least one dimension in the range 6-30 nm connected to nano-pores having at least one respective dimension in the range 1-5 nm.

An amorphous thin film stack can include a first layer including a combination metals or metalloids including: 5 at % to in 90 at % of a metalloid; 5 at % to 90 at % of a first metal and a second metal independently selected from titanium, vanadium, chromium, iron, cobalt, nickel, niobium, molybdenum, ruthenium, rhodium, palladium, tantalum, tungsten, osmium, iridium, or platinum. The three elements may account for at least 70 at % of the amorphous thin film stack. The stack can further include a second layer formed on a surface of the first layer. The second layer can be an oxide layer, a nitride layer, or a combination thereof. The second layer can have an average thickness of 10 angstroms to 200 microns and a thickness variance no greater than 15% of the average thickness of the second layer.

A method for sealing an access opening to a cavity comprises the following steps: providing a layer arrangement having a first layer structure and a cavity arranged adjacent to the first layer structure, wherein the first layer structure has an access opening to the cavity, performing a CVD layer deposition for forming a first covering layer having a layer thickness on the first layer structure having the access opening, and performing an HDP layer deposition with a first and second substep for forming a second covering layer on the first covering layer, wherein the first substep comprises depositing a liner material layer on the first covering layer, wherein the second substep comprises partly backsputtering the liner material layer and furthermore the first covering layer in the region of the access opening, and wherein the first and second substeps are carried out alternately and repeatedly a number of times.

Deep via technology is used to construct an integrated silicon cantilever and cavity oriented in a vertical plane which creates an electrostatically-switched MEMS switch in a small wafer area. Another embodiment is a small wafer area electrostatically-switched, vertical-cantilever MEMS switch wherein the switch cavity is etched within a volume defined by walls grown internally within a silicon substrate using through vias.

A method of fabricating a semiconductor device, includes, in part, growing a first layer of oxide on a surface of a first semiconductor substrate, forming a layer of insulating material on the oxide layer, patterning and etching the insulating material and the first oxide layer to form a multitude of oxide-insulator structures and further to expose the surface of the semiconductor substrate, growing a second layer of oxide in the exposed surface of the semiconductor substrate, and removing the second layer of oxide thereby to form a cavity in which a MEMS device is formed. The process of growing oxide in the exposed surface of the cavity and removing this oxide may be repeated until the cavity depth reaches a predefined value. Optionally, a multitude of bump stops is formed in the cavity.

Deep via technology is used to construct an integrated silicon cantilever and cavity oriented in a vertical plane which creates an electrostatically-switched MEMS switch in a small wafer area. Another embodiment is a small wafer area electrostatically-switched, vertical-cantilever MEMS switch wherein the switch cavity is etched within a volume defined by walls grown internally within a silicon substrate using through vias.

The invention is a process for producing an electromechanical device including a movable portion that is able to deform with respect to a fixed portion. The process implements steps based on fabrication microtechnologies, applied to a substrate including an upper layer, an intermediate layer and a lower layer. These steps are: a) forming first apertures in the upper layer; b) forming an empty cavity in the intermediate layer, which step is referred to as a pre-release step because a central portion of the upper layer lying between the first apertures is pre-released; c) applying what is called a blocking layer to the upper layer, this layer covering the first apertures, the blocking layer and the central portion together forming a suspended microstructure above the empty cavity; d) producing a boundary trench in the suspended microstructure, so as to form, in this microstructure, a movable portion and a fixed portion, the movable portion forming a movable member of the electromechanical device.