Described herein are manufacturing techniques for achieving stress isolation in microelectromechanical systems (MEMS) devices that involve isolation trenches formed from the backside of the substrate. The techniques described herein involve etching a trench in the bottom side of the substrate subsequent to forming a MEMS platform, and processing the MEMS platform to form a MEMS device on the top side of the substrate subsequent to etching the trench.

A MEMS device is formed by a body of semiconductor material which defines a support structure. A pass-through cavity in the body is surrounded by the support structure. A movable structure is suspended in the pass-through cavity. An elastic structure extends in the pass-through cavity between the support structure and the movable structure. The elastic structure has a first and second portions and is subject, in use, to mechanical stress. The MEMS device is further formed by a metal region, which extends on the first portion of the elastic structure, and by a buried cavity in the elastic structure. The buried cavity extends between the first and the second portions of the elastic structure.

A method for producing at least one deformable membrane micropump including a first substrate and a second substrate assembled together, the first substrate including at least one cavity and the second substrate including at least one deformable membrane arranged facing the cavity. In the method: the cavity is produced in the first substrate; then the first and second substrates are assembled together; then the deformable membrane is produced in the second substrate.

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.

Structures, materials, and methods to control the spread of a solder material or other flowable conductive material in electronic and/or electromagnetic devices are provided.

A structure and method of fabricating suspended beam silicon carbide MEMS structure with low capacitance and good thermal expansion match. A suspended material structure is attached to an anchor material structure that is direct wafer bonded to a substrate. The anchor material structure and the suspended material structure are formed from either a hexagonal single-crystal SiC material, and the anchor material structure is bonded to the substrate while the suspended material structure does not have to be attached to the substrate. The substrate may be a semi-insulating or insulating SiC substrate. The substrate may have an etched recess region on the substrate first surface to facilitate the formation of the movable suspended material structures. The substrate may have patterned electrical electrodes on the substrate first surface, within recesses etched into the substrate.

The present disclosure provides a CMOS structure, including a substrate, a metallization layer over the substrate, a sensing structure over the metallization layer, and a signal transmitting structure adjacent to the sensing structure. The sensing structure includes an outgassing layer over the metallization layer, a patterned outgassing barrier over the outgassing layer; and an electrode over the patterned outgassing barrier. The signal transmitting structure electrically couples the electrode and the metallization layer.

The present invention generally relates to multi-layer glass structures and methods of making the same.

There is provided a method for forming a composite cavity and a composite cavity formed using the method. The method comprises the following steps: providing a silicon substrate (101); forming an oxide layer on the front side thereof; patterning the oxide layer to form one or more grooves (103), the position of the groove (103) corresponding to the position of small cavity (109) to be formed; providing a bonding wafer (104), which is bonded to the patterned oxide layer to form one or more closed micro-cavity structures (105) between the silicon substrate (101) and the bonding wafer (104); forming a protective film (106) over the bonding wafer (104) and forming a masking layer (107) on the back side of the silicon substrate (101); patterning the masking layer (107), the pattern of the masking layer (107) corresponding to the position of a large cavity (108) to be formed; using the masking layer (107) as a mask, etching the silicon substrate (101) from the back side until the oxide layer at the front side thereof to form the large cavity (108) in the silicon substrate (101); and using the masking layer (107) and the oxide layer as a mask, etching the bonding wafer (104) from the back side through the silicon substrate (101) until the protective film (106) thereover to form one or more small cavities (109) in the bonding wafer (104). The uniformity of thickness of the semiconductor medium layer where the small cavity (109) in the composite cavity is located is well controlled by the present invention.

A micromechanical sensor includes a base substrate, a cap substrate, and a MEMS substrate that is connected to each of the base and cap substrates by respective metallic bond connections and that includes a mechanical functional layer including movable MEMS elements, an electrode device for acquiring an indication of a movement of the MEMS elements and fashioned by layer deposition, and a sacrificial layer that is lower than the mechanical function layer, is fashioned by layer deposition, and is omitted in a region underneath the movable MEMS elements.