A method for locally removing/modifying a polymer material on a surface of a wafer. The method includes: a) aligning a mask with respect to the surface; b) locally exposing the surface through the mask using a VUV light source while simultaneously supplying a gas mixture containing at least oxygen; c) purging the surface with a gas mixture containing at least nitrogen and oxygen, the VUV light source being switched off; and d) repeating at least steps b) and c) until the removal/modification is complete. A device is described for locally removing/modifying a polymer material on a surface of a wafer, including a mask. The device includes an adjustable wafer table for holding the wafer, and is configured to set an exposure gap between the wafer and the mask in a first operating state, and to set a purge gap between the wafer and the mask in a second operating state.

A corrosion method of a passivation layer (320) of a silicon wafer (300) includes: pouring hydrofluoric acid solution (100) into a container (200) with an open top; putting the silicon wafer (300) to the opening of the container (200) and one side of the silicon wafer (300) with the passivation layer (320) is opposite to the hydrofluoric acid solution (100); the hydrogen fluoride gas generated from the volatilization of the hydrofluoric acid solution (100) corrodes the passivation layer (320) of the silicon wafer (300), the corrosion time is larger or equal to (thickness of the passivation layer/corrosion rate). By means of the corrosion of the passivation layer of silicon wafer by the fluoride gas generated from the volatilization of the hydrofluoric acid solution, the fluoride gas can fully touch the passivation layer; therefore the passivation layer can be completely corroded, and the corrosion precision is high.

Provided is a PCB speaker and a method for micromachining the speaker diaphragm on PCB substrate, the method for micromachining the speaker diaphragm on PCB substrate comprises: providing metal paths and at least one through hole on the PCB substrate; providing a patterned sacrificial layer on the PCB substrate, the sacrificial layer covering all the through holes on the PCB substrate; providing a diaphragm layer on the sacrificial layer through depositing, mounting or laminating, the diaphragm layer covering the sacrificial layer and electrically connected with the metal paths on the PCB substrate, thereby forming a diaphragm layer; and releasing the sacrificial layer and the diaphragm layer remains. With the micromachining method for the above PCB substrate and the diaphragm, the production cost of the speaker can be lowered, and the reliability of the product can be improved at the same time.

A sensor device is described. The sensor device includes at least one substrate; an edge region that is disposed on the substrate and laterally delimits an inner region above the substrate; a diaphragm that is anchored on the edge structure and at least partly spans the inner region, the diaphragm encompassing in the inner region at least one region which is movable by way of a pressure and which encloses a cavity between the diaphragm and the substrate; and a first intermediate carrier that extends in the movable region below the diaphragm and is connected to the diaphragm, and in particular has at least one trench.

According to at least one embodiment, a method of fabricating a micro electro-mechanical systems (MEMS) structure is disclosed. The method involves causing an etchant to remove a portion of a sacrificial layer of the MEMS structure, the sacrificial layer between a structural layer of the MEMS structure and a substrate of the MEMS structure. In this embodiment, causing the etchant to remove the portion of the sacrificial layer involves causing a target portion of the substrate to be released from the MEMS structure. According to another embodiment, another method of fabricating a MEMS structure is disclosed. The method involves causing an etchant including water to remove a portion of a sacrificial layer of the MEMS structure, the sacrificial layer between a structural layer of the MEMS structure and a substrate of the MEMS structure. In this embodiment, the sacrificial layer and the substrate are hydrophobic.

In an embodiment, a method for manufacturing a micro-electro-mechanical systems (MEMS) transducer device includes providing a substrate body with a surface, depositing an etch-stop layer (ESL) on the surface, depositing a sacrificial layer on the ESL, depositing a diaphragm layer on the sacrificial layer and removing the sacrificial layer, wherein depositing the sacrificial layer includes depositing a first sub-layer of a first material and depositing a second sub-layer of a second material, and wherein the first material and the second material are different materials.

A MEMS device is provided. The MEMS device includes a substrate having at least one contact, a first dielectric layer disposed on the substrate, at least one metal layer disposed on the first dielectric layer, a second dielectric layer disposed on the first dielectric layer and the metal layer and having a recess structure, and a structure layer disposed on the second dielectric layer and having an opening. The opening is disposed on and corresponds to the recess structure, and the cross-sectional area at the bottom of the opening is smaller than the cross-sectional area at the top of the recess structure. The MEMS device also includes a sealing layer, and at least a portion of the sealing layer is disposed in the opening and the recess structure. The second dielectric layer, the structure layer, and the sealing layer define a chamber.

A micro electro mechanical system (MEMS) includes a circuit substrate, a first MEMS structure disposed over the circuit substrate, and a second MEMS structure disposed over the first MEMS structure.

A method of manufacturing a semiconductor structure includes following operations. A first substrate is provided. A plate is formed over the first substrate. The plate includes a first tensile member, a second tensile member, a semiconductive member between the first tensile member and the second tensile member, and a plurality of apertures penetrating the first tensile member, the semiconductive member and the second tensile member. A membrane is formed over and separated from the plate. The membrane include a plurality of holes. A plurality of conductive plugs passing through the plate or membrane are formed. A plurality of semiconductive pads are formed over the plurality of conductive plugs. The plate is bonded to a second substrate. The second substrate includes a plurality of bond pads, and the semiconductive pads are in contact with the bond pads.

Embodiments described herein relate to the concept and designs of a polymer-based thermal ground plane. In accordance with one embodiment, a polymer is utilized as the material to fabricate the thermal ground plane. Other embodiments include am optimized wicking structure design utilizing two arrays of micropillars, use of lithography-based microfabrication of the TGP using copper/polymer processing, micro-posts, throttled releasing holes embedded in the micro-posts, atomic layer deposition (ALD) hydrophilic coating, throttled fluid charging structure and sealing method, defect-free ALD hermetic coating, and compliant structural design.