A semiconductor device and a method of manufacturing the same are provided. The semiconductor device includes a substrate having a first surface and a second surface arranged opposite to the first surface; a stress-sensitive sensor disposed at the first surface of the substrate, where the stress-sensitive sensor is sensitive to mechanical stress; a stress-decoupling trench that has a vertical extension that extends from the first surface into the substrate, where the stress-decoupling trench vertically extends partially into the substrate towards the second surface although not completely to the second surface; and a plurality of particle filter trenches that vertically extend from the second surface into the substrate, wherein each of the plurality of particle filter trenches have a longitudinal extension that extends orthogonal to the vertical extension of the stress-decoupling trench.

A method for forming a MEMS structure for an inertial sensor from fused silica includes: depositing a conductive layer on one or more selected regions of a first surface of a fused silica substrate, and illuminating areas of the fused silica substrate with laser radiation in a pattern defining features of the MEMS structure for an inertial sensor. A masking layer is deposited at least on the one or more selected regions of the first surface of the fused silica substrate where the conductive layer has been deposited, such that the illuminated areas of the fused silica substrate remain exposed. A first etch of the exposed areas of the fused silica substrate is performed so as to selectively etch the pattern defining features of the MEMS structure for an inertial sensor.

A MEMS infrared sensing device includes a substrate and an infrared sensing element. The infrared sensing element is provided above the substrate and has a sensing area and an infrared absorbing area which do not overlap each other. The infrared sensing element includes two infrared absorbing structures, an infrared sensing layer provided between the two infrared absorbing structures, and an interdigitated electrode structure located in the sensing area. Each of the two infrared absorbing structures includes at least one infrared absorbing layer, and the two infrared absorbing structures are located in the sensing area and the infrared absorbing area. The infrared sensing layer is located in the sensing area and does not extend into the infrared absorbing area. The interdigitated electrode structure is in electrical contact with the infrared sensing layer.

Techniques relating to a micro-electro-mechanical (MEMS) device configured to measure direct axial and shear stress components of a stress tensor are described. The MEMS device includes a first and second circuit configured in a double rosette structure coupled with a third circuit in a standard rosette structure to form a triple rosette piezo-resistive gauge circuit. The first circuit includes at least one piezoresistive element suspended from a substrate, and at least one piezoresistive element fixed to the substrate. The second circuit includes each piezoresistive element fixed to the substrate. The third circuit includes at least one piezoresistive element fixed to the substrate. Additionally, the MEMS device may be coupled to one or more processing systems to determine a mechanical stress tensor that is applied to the MEMS device based on measurements received from the MEMS device.

A semiconductor pressure sensor includes a fixed electrode placed at a principal surface of a semiconductor substrate, and a diaphragm movable through an air gap in a thickness direction of the semiconductor substrate at least in an area where the diaphragm is opposed to the fixed electrode. The diaphragm includes: a movable electrode; a first insulation film placed closer to the air gap with respect to the movable electrode; a second insulation film placed opposite to the air gap with respect to the movable electrode, the second insulation film being of a same film type as the first insulation film; and a shield film that sandwiches the second insulation film with the movable electrode.

A micro-electromechanical system (MEMS) device includes a silicon substrate; and a Tantalum (Ta) layer comprising a first portion and a second portion, a first portion being suspended over the silicon substrate and configured to move relative to the silicon substrate, and the second portion of the structure being coupled to the silicon substrate and fixed in place relative to the silicon substrate.

A MEMS sensor includes: a conductive device-side substrate including cavity in thickness direction thereof; a MEMS electrode arranged in the cavity; a support extending in first direction toward the MEMS electrode from peripheral wall of the cavity and connected to and support the MEMS electrode; and an isolator traversing the support in second direction in plan view to isolate the support into a first support on the side of the MEMS electrode and a second support on the side of the device-side substrate to be electrically insulated from each other in the first direction, wherein the isolator includes: a trench recessed in the thickness direction with respect to the device-side substrate; insulating layers formed on inner wall surfaces of the trench; and joining layers formed on the insulating layers and including portions facing each other and at least partially joined to each other in the first direction.

A semiconductor package and a method of manufacturing a semiconductor package. As a non-limiting example, various aspects of this disclosure provide a semiconductor package, and a method of manufacturing thereof, that comprises a first semiconductor die, a plurality of adhesive regions spaced apart from each other on the first semiconductor die, and a second semiconductor die adhered to the plurality of adhesive regions.

A microscale device comprises a patterned forest of vertically grown and aligned carbon nanotubes defining a carbon nanotube forest with the nanotubes having a height defining a thickness of the forest, the patterned forest defining a patterned frame that defines one or more components of a microscale device. A conformal coating of substantially uniform thickness at least partially coats the nanotubes, defining coated nanotubes and connecting adjacent nanotubes together, without substantially filling interstices between individual coated nanotubes. A metallic interstitial material infiltrates the carbon nanotube forest and at least partially fills interstices between individual coated nanotubes.

A pressure sensor includes a silicon substrate which has a diaphragm, a frame-shaped side wall section which is placed on one surface side of the silicon substrate so as to surround the diaphragm in a plan view, a lid section which is placed so as to cover an opening of the side wall section and has a through-hole communicating inside and outside the side wall section, a sealing section which is placed on the lid section and seals the through-hole, and a pressure reference chamber which is defined by the silicon substrate, the side wall section, the lid section, and the sealing section, wherein a surface facing the pressure reference chamber of each of the side wall section and the lid section contains a silicon material.