In one example, an apparatus that is part of a Light Detection and Ranging (LiDAR) module of a vehicle comprises a semiconductor integrated circuit comprising a microelectromechanical system (MEMS) and a substrate. The MEMS comprises an array of micro-mirror assemblies, each micro-mirror assembly comprising: a micro-mirror having a first thickness; and an actuator comprising first fingers and second fingers, the first fingers being connected with the substrate, the second fingers being mechanically connected to the micro-mirror having a second thickness smaller than the first thickness, the actuator being configured to generate an electrostatic force between the first fingers and the second fingers to rotate the micro-mirror to reflect light emitted by a light source out of the LiDAR module or light received by the LiDAR module to a receiver.

A method for manufacturing a micromechanical sensor. The method includes: applying a first oxide sacrificial layer onto a substrate; removing material of the substrate through openings in the first oxide sacrificial layer; closing the openings in the first oxide sacrificial layer by applying a second oxide sacrificial layer; forming a sensing area on a carrier structure, the sensing area and the carrier structure being formed on the oxide sacrificial layers and the sensing area and/or the carrier structure being connected to the substrate via at least one attachment area, which forms a flexible structure; and at least partially removing the oxide sacrificial layers between the carrier structure and the substrate with the aid of an etching process.

One or more methods of fabricating a microscale canopy wick structure having an array of individual wicks having one or more canopy members. Each method includes selectively etching a substrate to control the thickness of the canopy members and also control the width of a fluid flow channel between adjacent wicks in a manner that enhances the overall performance of the microscale canopy wick structure.

A method of manufacturing a MEMS device, wherein the MEMS device has a cavity in which a beam will move to change the capacitance of the device. After most of the device build-up has occurred, sacrificial material is removed to free the beam within the MEMS device cavity. Thereafter, exposed ruthenium contacts are etched back with an etchant comprising chlorine to remove the top surface of both the top and bottom contacts. Due to this etch back process, low contact resistance can be achieved with less susceptibility to stiction events. Stiction performance can be further improved by conditioning the ruthenium contacts in a fluorine based plasma. The fluorine based plasma process, or fluorine treatment, can be performed prior to or after etch-back process of the ruthenium contacts.

In various embodiments, electronic devices such as touch-panel displays incorporate interconnects featuring a conductor layer and, disposed above the conductor layer, a capping layer comprising an alloy of Cu and one or more refractory metal elements selected from the group consisting of Ta, Nb, Mo, W, Zr, Hf, Re, Os, Ru, Rh, Ti, V, Cr, and Ni.

A method for producing a thin-film layer includes providing a layer stack on a carrier substrate, wherein the layer stack includes a carrier layer and a sacrificial layer, and wherein the sacrificial layer includes areas in which the carrier layer is exposed. The method includes providing the thin-film layer on the layer stack, such that the thin-film layer bears on the sacrificial layer and, in the areas of the sacrificial layer in which the carrier layer is exposed, against the carrier layer. The method includes at least partly removing the sacrificial layer from the thin-film layer in order to eliminate a contact between the thin-film layer and the sacrificial layer in some areas. The method also includes detaching the thin-film layer from the carrier layer.

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.

A micro-device structure comprises a source substrate having a sacrificial layer comprising a sacrificial portion adjacent to an anchor portion, a micro-device disposed completely over the sacrificial portion, the micro-device having a top side opposite the sacrificial portion and a bottom side adjacent to the sacrificial portion and comprising an etch hole that extends through the micro-device from the top side to the bottom side, and a tether that physically connects the micro-device to the anchor portion. A micro-device structure comprises a micro-device disposed on a target substrate. Micro-devices can be any one or more of an antenna, a micro-heater, a power device, a MEMs device, and a micro-fluidic reservoir.

An apparatus includes a lens material forming a lens. The apparatus also includes a piezoelectric capacitor over the lens material, where the piezoelectric capacitor is configured to change a shape of the lens material in response to a voltage across the piezoelectric capacitor to thereby change a focus of the lens. The apparatus further includes at least one stress compensation ring over a portion of the lens material and over at least a portion of the piezoelectric capacitor. The at least one stress compensation ring is configured to at least partially reduce bending of the lens material caused by stress on or in the lens material.

In various embodiments, electronic devices such as touch-panel displays incorporate interconnects featuring a conductor layer and, disposed above the conductor layer, a capping layer comprising an alloy of Cu and one or more refractory metal elements selected from the group consisting of Ta, Nb, Mo, W, Zr, Hf, Re, Os, Ru, Rh, Ti, V, Cr, and Ni.