In described examples, a hermetic package of a microelectromechanical system (MEMS) structure includes a substrate having a surface with a MEMS structure of a first height. The substrate is hermetically sealed to a cap forming a cavity over the MEMS structure. The cap is attached to the substrate surface by a vertical stack of metal layers adhering to the substrate surface and to the cap. The stack has a continuous outline surrounding the MEMS structure while spaced from the MEMS structure by a distance. The stack has: a first bottom metal seed film adhering to the substrate and a second bottom metal seed film adhering to the first bottom metal seed film; and a first top metal seed film adhering to the cap and a second top metal seed film adhering to the first top metal seed film.

Provided is a microfluidic film including a base film, a microchannel, which is formed on the base film and through which a fluid flows, and a through passage, which is configured to pass through the base film and through which the base film stacked on an upper portion or a lower portion of the base film and the fluid communicate with each other.

In described examples, a MEMS device is formed by forming a sacrificial layer over a substrate and forming a first metal layer over the sacrificial layer. Subsequently, the first metal layer is exposed to an oxidizing ambient which oxidizes a surface layer of the first metal layer where exposed to the oxidizing ambient, to form a native oxide layer of the first metal layer. A second metal layer is subsequently formed over the native oxide layer of the first metal layer. The sacrificial layer is subsequently removed, forming a released metal structure.

A micro-structure is manufactured by patterning a sacrificial film, forming an inorganic material film on the pattern, providing the inorganic material film with an aperture, and etching away the sacrificial film pattern through the aperture to define a space having the contour of the pattern. The patterning stage includes the steps of (A) forming a sacrificial film using a composition comprising a cresol novolac resin and a crosslinker, (B) exposing patternwise the film to first high-energy radiation, (C) developing, and (D) exposing the sacrificial film pattern to second high-energy radiation and heat treating for thereby forming crosslinks within the cresol novolac resin.

The present disclosure provides a substrate structure for a micro electro mechanical system (MEMS) device. The substrate structure includes a cap and a micro electro mechanical system (MEMS) substrate. The cap has a cavity, and the MEMS substrate is disposed on the cap. The MEMS substrate has a plurality of through holes exposing the cavity, and an aspect ratio of the through hole is greater than 30.

Method for encapsulation of a microelectronic component, including making of a portion of sacrificial material on a front face of a first substrate in which the component is intended to be made, then making of a cover encapsulating the portion of sacrificial material, then making of the component by etching the first substrate from its back face, such that part of the component is arranged to face the portion of sacrificial material and such that the portion of sacrificial material is accessible from a back face of the component, then elimination of the portion of sacrificial material by etching from the back face of the component, then securing of the back face of the component to a second substrate.

In an example, a method includes depositing an organic polymer layer on one or more material layers. The method also includes thermally curing the organic polymer layer. The method includes depositing a hard mask on the organic polymer layer and depositing a photoresist layer on the hard mask. The method also includes patterning the photoresist layer to expose at least a portion of the hard mask. The method includes etching the exposed portion of the hard mask to expose at least a portion of the organic polymer layer. The method also includes etching the exposed portion of the organic polymer layer to expose at least a portion of the one or more material layers.

Provided is a pressure sensor. The pressure sensor has a sensing region and a non-sensing region, and includes: a first flexible film layer, wherein a first groove is disposed in a first surface of the first flexible film layer, and the first groove is within the sensing region; a first electrode layer; a first insulative layer, disposed on a side, distal from the first flexible film layer, of the first electrode layer; a second electrode layer, wherein the second electrode layer is disposed on a side, distal from the first flexible film layer, of the first insulative layer; and a second flexible film layer, wherein the second flexible film layer is disposed on a side, distal from the first flexible film layer, of the second electrode layer.

A hermetic package comprising a substrate (110) having a surface with a MEMS structure (101) of a first height (101a), the substrate hermetically sealed to a cap (120) forming a cavity over the MEMS structure; the cap attached to the substrate surface by a vertical stack (130) of metal layers adhering to the substrate surface and to the cap, the stack having a continuous outline surrounding the MEMS structure while spaced from the MEMS structure by a distance (140); the stack having a bottom first metal seed film (131a) adhering to the substrate and a bottom second metal seed film (131b) adhering to the bottom first seed film, both seed films of a first width (131c) and a common sidewall (138); further a top first metal seed film (132a) adhering to the cap and a top second metal seed film (132b) adhering to the top first seed film, both seed films with a second width (132c) smaller than the first width and a common sidewall (139); the bottom and top metal seed films tied to a metal layer (135) including gold-indium intermetallic compounds, layer (135) having a second height (133a) greater than the first height and encasing the seed films and common sidewalls.

A hermetic package comprising a substrate (110) having a surface with a MEMS structure (101) of a first height (101a), the substrate hermetically sealed to a cap (120) forming a cavity over the MEMS structure; the cap attached to the substrate surface by a vertical stack (130) of metal layers adhering to the substrate surface and to the cap, the stack having a continuous outline surrounding the MEMS structure while spaced from the MEMS structure by a distance (140); the stack having a bottom first metal seed film (131a) adhering to the substrate and a bottom second metal seed film (131b) adhering to the bottom first seed film, both seed films of a first width (131c) and a common sidewall (138); further a top first metal seed film (132a) adhering to the cap and a top second metal seed film (132b) adhering to the top first seed film, both seed films with a second width (132c) smaller than the first width and a common sidewall (139); the bottom and top metal seed films tied to a metal layer (135) including gold-indium intermetallic compounds, layer (135) having a second height (133a) greater than the first height and encasing the seed films and common sidewalls.