Abstract: Plural semiconductor chips such as acceleration sensor chips formed on the first surface of a substrate are separated into individual pieces by dicing the substrate from the second surface thereof. A groove surrounding each sensor chip, along which the sensor chip is diced out, is formed at the same time the sensor chip is formed on the first surface. Before dicing, a protecting sheet covering the first surface is pasted along the sidewalls and the bottom wall of the groove. The groove is made sufficiently wide to ensure that the protecting sheet is bent along the walls of the groove without leaving a space between the groove and the protecting sheet. Thus, dicing dusts generated in the dicing process are prevented from being scattered and entering the sensor chip.

Abstract: Plural semiconductor chips such as acceleration sensor chips formed on the first surface of a substrate are separated into individual pieces by dicing the substrate from the second surface thereof. A groove surrounding each sensor chip, along which the sensor chip is diced out, is formed at the same time the sensor chip is formed on the first surface. Before dicing, a protecting sheet covering the first surface is pasted along the sidewalls and the bottom wall of the groove. The groove is made sufficiently wide to ensure that the protecting sheet is bent along the walls of the groove without leaving a space between the groove and the protecting sheet. Thus, dicing dusts generated in the dicing process are prevented from being scattered and entering the sensor chip.

Abstract: In a method for manufacturing a semiconductor acceleration sensor, a movable portion including a mass portion and movable electrodes is formed in a single crystal silicon thin film provided on a silicon wafer through an insulation film by etching both the single crystal silicon thin film and the silicon wafer. In this case, the movable portion is finally defined at a movable portion defining step that is carried out in a vapor phase atmosphere. Accordingly, the movable portion is prevented from sticking to other regions due to etchant during the manufacture thereof.

Abstract: A semiconductor accelerometer device is formed on an SOI substrate by micro-machining. A movable unit is supported at both ends, and a weight portion is movable in response to acceleration exerted in the detection direction. A movable electrode is formed in a comb shape integrally with the weight portion. A pair of fixed electrodes in a comb shape are cantilevered and interleaved with the movable electrode to face the movable electrode. A plurality of through holes is provided in the electrodes so that the electrodes have Rahmen structure which is a series of rectangular frames. This structure reduces the weight of each electrode while increasing the strength against twist force. The electrodes are less likely from breaking in response to an acceleration exerted in a direction perpendicular to the normal detection direction because of reduced weight.

Abstract: A semiconductor strain sensor has a gauge forming region on a p-type substrate surrounded by a p-type isolation region that reaches the p-type substrate. The p-type substrate is etched so that the entire bottom surface of the gauge forming region is covered by the p-type substrate, and the p-type substrate or p-type isolation region is not exposed to the etched recess portion or isolation groove, each of which have a relatively high number of defects. Thus, leakage current at the PN junction can be decreased to decrease a variation in the potential of the gauge forming region.

Abstract: In the present invention, a first protective layer formed over a diaphragm is prevented from being etched unnecessarily at the time of etching a second protective layer, and the detection accuracy of the diaphragm is improved.In a process for producing a semiconductor pressure sensor, a first protective layer 4, a metal layer 8 and a second protective layer 6 are successively formed by deposition over a diaphragm 1a, and the second protective layer 6 is removed by etching so that the second protective layer 6 is left on a predetermined portion of an electrode 5. Since the metal layer 8 acts as an etching stopper layer at the time of removing the second protective layer 6 by etching, the first protective layer 4 over the diaphragm 1a is prevented from being etched. The metal layer 8 is removed by etching thereafter so that only the first protective layer 4 is formed over the diaphragm 1a.

Abstract: It is intended to provide an etching method for semiconductor devices in which the etching depth or the thickness of a thin thickness portion can be precisely controlled. According to experiment results, when a P-type substrate in which an N-type epitaxial layer is formed is immersed in an etching solution such as KOH or the like, and a voltage for reverse bias of PN junction is applied between an electrode plate opposing the substrate and the epitaxial layer to perform electrochemical etching, it has been found that the distance from the PN junction plane to the etching stop position is approximately equal to a depletion layer width at the substrate side of the PN junction portion. Namely, the etching stops at the forward end of the depletion layer.

Abstract: A semiconductor strain sensor includes a base, a peripheral section, a central section and a flexible beam. The peripheral section is bent to the base. Bonding strain is generated at a bonding portion between the base and the peripheral section. The central section extends from the peripheral section. The flexible beam extends from the central section and includes a strain detecting element. The strain detecting element changes its electric characteristic when strain is applied thereto. A thickness of the flexible beam is thinner than that of the central section. The bonding strain is transmitted from the bonding portion to the strain detecting element through a transmission path. The transmission path is bent. The bonding strain is attenuated because it is dispersed at a bending portion of the transmission path. The sensor accurately detects the strain to be detected without a bad influence of the bonding strain.