A micro-device including at least one first element comprising at least: a portion of material corresponding to a compound of at least one semi-conductor and at least one metal, first and second protective layers each covering one of two opposite faces of said portion of material, such that the first and second protective layers are in direct contact with said portion of material, that the first protective layer comprises at least one first material able to withstand an HF etching, that the second protective layer comprises at least one second material able to withstand the HF etching, and that at least one of the first and second materials able to withstand the HF etching includes the semi-conductor.

In embodiments, a silicon part and a titanium part may be soldered together without breakage or instability. In embodiments, silicon and titanium may be soldered together with a soft solder joint including indium silver, where the temperature excursion between solder solidus and use temperature limits the strain between the two surfaces. In embodiments a silicon micropump surface may be treated to remove its silicon oxide coating, and then TiW, Nickel, and gold layers successively sputtered onto it. A corresponding titanium manifold may be ground flat, and plated with electroless nickel. The nickel plated manifold may then be baked, so as to create a transition from pure Ti to NiTi alloy to pure Ni at the surface of the manifold, and for protection of the upper Ni surface, a layer of gold may be added. The two surfaces may then be soldered in forming gas.

The invention is directed to a microfluidic device, which comprises distinct, parallel levels, including a first level and a second level. It further includes: a first microchannel, a second microchannel, and a node. This node comprises: an inlet port, a cavity, a via, and an outlet port. The cavity is formed on the first level and is open on a top side. The inlet port is defined on the first level; it branches from the first microchannel and communicates with the cavity through an ingress thereof. The outlet port, branches to the second microchannel on the second level. The via extends from the bottom side of the cavity, down to the outlet port, so the cavity may communicate with the outlet port. In addition, the cavity comprises a liquid blocking element to prevent an aqueous liquid filling the inlet port to reach the outlet port.

The present disclosure provides methods and apparatuses for biomaterial detection sensors. In some embodiments, a biomaterial detection sensor includes a membrane including a plurality of wells. Each of the plurality of wells is configured to encapsulate a biomaterial contained in a sample solution. A surface of the membrane is selectively modified into at least one of a hydrophilic surface and a hydrophobic surface. In some embodiments, a method of manufacturing a biomaterial detection sensor includes depositing a first membrane and a second membrane on respective surfaces of a wafer, forming a window by etching the first membrane and the first surface of the wafer, forming a plurality of wells on the second membrane, modifying a surface of the second membrane into at least one of a hydrophilic surface and a hydrophobic surface; and transferring a two-dimensional graphene oxide material onto a bottom of each of the plurality of wells.

The damascene wiring structure includes a base including a main surface provided with a groove, an insulating layer including a first portion provided on an inner surface of the groove and a second portion provided on the main surface, a metal layer provided on the first portion, a wiring portion embedded in the groove, and a cap layer provided to cover the second portion and the wiring portion. A surface of a boundary part between the first portion and the second portion includes an inclined surface inclined with respect to a direction perpendicular to the main surface.

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.

A method and apparatus are for controlling stress variation in a material layer formed via pulsed DC physical vapour deposition. The method includes the steps of providing a chamber having a target from which the material layer is formed and a substrate upon which the material layer is formable, and subsequently introducing a gas within the chamber. The method further includes generating a plasma within the chamber and applying a first magnetic field proximate the target to substantially localise the plasma adjacent the target. An RF bias is applied to the substrate to attract gas ions from the plasma toward the substrate and a second magnetic field is applied proximate the substrate to steer gas ions from the plasma to selective regions upon the material layer formed on the substrate.

A micromechanical structure comprises a substrate and a functional structure arranged at the substrate. The functional structure comprises a functional region which is deflectable with respect to the substrate responsive to a force acting on the functional region. The functional structure comprises a carbon layer arrangement, wherein a basis material of the carbon layer arrangement is a carbon material.

A micromechanical structure includes a substrate and a functional structure arranged at the substrate. The functional structure has a functional region configured to deflect with respect to the substrate responsive to a force acting on the functional region. The functional structure includes a conductive base layer and a functional structure comprising a stiffening structure having a stiffening structure material arranged at the conductive base layer and only partially covering the conductive base layer at the functional region. The stiffening structure material includes a silicon material and at least a carbon material.

For the purpose of shortening the MEMS manufacturing TAT, the MEMS manufacturing method according to the present invention includes a step of extracting the first MEMS with first characteristic in a range approximate to the required characteristic from the plurality of MEMS preliminarily prepared on the main surface of the substrate, and a step of forming a second MEMS having the required characteristic by directly processing the first MEMS.