Abstract: There are included a semiconductor substrate provided with a desirable element region, an electrode pad formed to come in contact with a surface of the semiconductor substrate or a wiring layer provided on the surface of the semiconductor substrate, a bump formed on a surface of the electrode pad through an intermediate layer, and a resin insulating film formed in at least a peripheral portion of the bump to cover an interface of the bump and the intermediate layer which is exposed to a side surface of the bump.

Abstract: MEMS sensor including substrate, lower thin film confronting one face of the substrate with a space therebetween and having lower through holes extending in the thickness direction thereof, and upper thin film arranged on the opposite side of the substrate confronting the lower thin film with a space therebetween and having upper through holes extending in the thickness direction. A MEMS sensor manufacturing method includes forming a first sacrificing layer on one face of a substrate, forming a lower thin film on the first sacrificing layer with lower through holes individually extending in the thickness direction, forming a second sacrificing layer on the lower thin film, forming an upper thin film on the second sacrificing layer with upper through holes individually extending in the thickness direction, removing the second sacrificing layer through the upper through holes by etching, and removing the first sacrificing layer through the upper and lower through holes by etching.

Abstract: The MEMS sensor according to the present invention includes: a substrate made of a silicon material, having a recess dug down from the surface thereof; a fixed electrode made of a metallic material, arranged in the recess and fixed to the substrate; and a movable electrode made of a metallic material, arranged in the recess to be opposed to the fixed electrode and provided to be displaceable with respect to the fixed electrode.

Abstract: An acceleration sensor includes a semiconductor element built in a substrate, a wiring layer formed on the substrate, and a piezoresistor, formed on the substrate and made up of a part of the wiring layer, whose resistivity changes by the action of acceleration.

Abstract: There are included a semiconductor substrate provided with a desirable element region, an electrode pad formed to come in contact with a surface of the semiconductor substrate or a wiring layer provided on the surface of the semiconductor substrate, a bonding pad formed on a surface of the electrode pad through an intermediate layer, and a resin insulating film for covering a peripheral edge of the bonding pad such that an interface of the bonding pad and the intermediate layer is not exposed to a side wall.

Abstract: An acceleration sensor of the present invention is a heat sensing type acceleration sensor, and includes a heating chip formed with a heating element on a surface thereof, and a sensor chip formed with a thermocouple element on a surface thereof and disposed so that the surface faces the surface of the heating chip.

Abstract: An MEMS (Micro Electro Mechanical Systems) sensor includes a base layer and a deformation portion provided on the base layer at an interval from the base layer and deformed by external force. The deformation portion is made of an organic material.

Abstract: A semiconductor device according to the present invention includes: a semiconductor substrate; a source region formed in a top layer portion of the semiconductor substrate; a drain region formed in the top layer portion of the semiconductor substrate and spaced apart from the source region; a gate electrode formed on the semiconductor substrate and opposing to an interval between the source region and the drain region; a wiring formed on the semiconductor substrate and connected to the source region, the drain region, or the gate electrode; and a MEMS sensor disposed on the semiconductor substrate. The MEMS sensor includes: a thin film first electrode made of the same material as the gate electrode and formed in the same layer as the gate electrode; and a second electrode made of the same material as the wiring, formed in the same layer as the wiring, and spaced apart from the first electrode at a side opposite to the semiconductor substrate side of the first electrode.

Abstract: The MEMS sensor according to the present invention includes: a substrate; a supporting portion provided on one surface of the substrate; a beam, supported by the supporting portion, having a movable portion opposed to the surface of the substrate through a space; a resistive conductor formed on at least the movable portion of the beam; a weight arranged on a side of the beam opposite to the substrate; and a coupling portion, made of a metallic material, coupling the beam and the weight with each other.

Abstract: A method of manufacturing an MEMS sensor according to the present invention includes the steps of: forming a first sacrificial layer on one surface of a substrate; forming a lower electrode on the first sacrificial layer; forming a second sacrificial layer made of a metallic material on the first sacrificial layer to cover the lower electrode; forming an upper electrode made of a metallic material on the second sacrificial layer; forming a protective film made of a nonmetallic material on the substrate to collectively cover the first sacrificial layer, the second sacrificial layer and the upper electrode; and removing at least the second sacrificial layer by forming a through-hole in the protective film and supplying an etchant to the inner side of the protective film through the through-hole.

Abstract: A pressure sensor of the present invention includes a lower substrate which has an insulating layer having a through-hole penetrating from one side to the other side, and an active layer formed to have a uniform thickness on the insulating layer and having a portion facing the through-hole as an oscillating portion capable of oscillating in a direction opposing the through-hole; a lower electrode formed on the oscillating portion; an upper substrate arranged opposite to the active layer and having a recess at a portion opposed to the oscillating portion; and an upper electrode formed on the recess.

Abstract: The acceleration sensor according to the present invention includes a sensor chip having a movable portion operating in response to a change in a physical quantity and a silicon chip arranged to be opposed to a first side of the sensor chip and bonded to the sensor chip, while the sensor chip is provided with a penetrating portion penetrating the sensor chip in the thickness direction so that the first side is visually recognizable from a second side of the sensor chip, and the silicon chip is provided with an alignment mark on a portion opposed to the penetrating portion.

Abstract: The method of etching a sacrificial layer according to the present invention includes the steps of forming a sacrificial layer having a protrusive shape on a base layer, forming a covering film covering the sacrificial layer, forming a protective film made of a material whose etching selection ratio to the sacrificial layer is greater than the etching selection ratio of the covering film to the sacrificial layer on a portion of the covering film opposed to the side surface of the sacrificial layer, and etching the sacrificial layer after the formation of the protective film.

Abstract: A semiconductor device provided with: a first interconnection layer provided on a semiconductor substrate; an interlevel insulation film provided over the first interconnection layer; a barrier layer provided between the first interconnection layer and the interlevel insulation film; and a second interconnection layer of gold provided as an uppermost interconnection layer on the interlevel insulation film. The barrier layer is formed in a region of the first interconnection layer including an interlevel connection opening region of the interlevel insulation, and the region is greater than the interlevel connection opening region. The second interconnection layer is electrically connected to the first interconnection layer via the barrier layer in the interlevel connection opening.

Abstract: The MEMS sensor according to the present invention includes a diaphragm.

Abstract: An MEMS sensor is described. The MEMS sensor may include a substrate, a lower thin film provided in contact with a surface of the substrate, and an upper thin film opposed to the lower thin film at an interval on the side opposite to the substrate.

Abstract: A semiconductor device according to the present invention includes a semiconductor substrate and an MEMS sensor provided on the semiconductor substrate.

Abstract: A semiconductor device according to the present invention includes a semiconductor substrate and an MEMS sensor provided on the semiconductor substrate. The MEMS sensor includes a vibratory first electrode and a plurality of second electrodes opposed to the first electrode at an interval.

Abstract: A semiconductor device of the present invention includes a semiconductor substrate, a semiconductor element formed in the semiconductor substrate, a surface layer formed on the semiconductor substrate, and a capacitance type sensor formed on the surface layer. The surface layer has a planar portion whose surface is planar. The capacitance type sensor includes a lower thin film parallelly opposed to the surface of the planar portion and an upper thin film opposed to the lower thin film at a prescribed interval on the side opposite to the surface layer.

Abstract: The MEMS sensor includes a substrate, a lower thin film, opposed to a surface of the substrate at an interval, having a plurality of lower through-holes formed to pass through the lower thin film in the thickness direction thereof, an upper thin film, opposed to the lower thin film at an interval on the side opposite to the substrate, having a plurality of upper through-holes formed to pass through the upper thin film in the thickness direction thereof, and a plurality of protrusions irregularly provided on a region of the surface of the substrate opposed to the lower thin film.