Abstract: A semiconductor device is provided. On one main surface side of an n-type semiconductor substrate, a p-type diffusion region to serve as an anode of a diode is formed. A guard ring formed of a p-type diffusion region is formed to surround the anode. On the other main surface side, an n-type ultrahigh-concentration impurity layer and an n-type high-concentration impurity layer to serve as a cathode are formed. In a guard-ring opposed region located in the cathode and opposite to the guard ring, a cathode-side p-type diffusion region is formed. Accordingly, concentration of the electric current on an outer peripheral end portion of the anode is suppressed.

Abstract: An MOS semiconductor device including an MOS gate structure is disclosed. The MOS semiconductor device includes a p-type well region selectively disposed on the surface layer of an n-type drift layer formed on a semiconductor substrate forming an n-type drain region; an n-type source region selectively disposed on the surface layer of the p-type well region; and a gate electrode placed, via an insulating film, on the surface of a channel formation region on the surface layer of the p-type well region sandwiched between the n-type source region and the surface layer of the n-type drain region, wherein a surface in the channel formation region has a level difference formed in the direction of the peripheral length, and all over the length, of the channel formation region.

Abstract: A MOS semiconductor device has a MOS structure, including a p? region that surrounds an n+-type source region and has a net doping concentration lower than a concentration of a p-type impurity in a surface of a p-type well region, and a gate electrode that is provided on top of the surface of the p-type well region sandwiched between the n+-type source region and a surface layer of an n? layer, with a gate insulator disposed between the p-type well region and the gate electrode. This configuration can make the gate insulator thicker without increasing a gate threshold voltage, and help improve the reliability of the gate insulator and reduce the gate capacitance.

Abstract: An information processing apparatus includes a communication unit and a control unit. The control unit is configured to be capable of controlling the communication unit to receive, from a different information processing apparatus, storage location information representing a storage location of key information necessary for encrypted wireless communication with the different information processing apparatus, to access the storage location represented by the storage location information to receive the key information, and to establish a connection with the different information processing apparatus by using the received key information.

Abstract: The present invention relates to a treatment device utilized in the freezing treatment method and its treatment planning device, and has an object to settle a freezing period·defrosting period according to a size of a treatment portion. A cryotherapy device comprises a gas supply-exhaust system 100, a control system 200 therefore and a freezing probe system 300. The gas supply-exhaust system 100 supplies a freezing gas and a defrosting gas to a probe 60 of the freezing probe system 300 to freeze and defrost the treatment portion surrounding the tip of the probe 60 by the Joule·Thomson effect. The control system 200 controls the gas supply-exhaust system 100 and makes treatment planning data for this control. The treatment planning data includes a freezing·defrosting sequence to determine the freezing period and the defrosting period. The determination of this sequence is performed by the computer in the control system 200.

Abstract: A semiconductor device has an active portion having at least one well region in a semiconductor layer, and a breakdown voltage maintaining structure surrounding the active portion. The maintaining structure includes a conductor layer over each of a plurality of guard rings with an insulating film interposed in between and connected to the respective guard ring. An inner side end portion of each conductor layer projects over the immediate adjacent inner side guard ring. The impurity concentration of the guard rings is set between the impurity concentrations of the semiconductor layer and the well regions. A field plate can extend over the innermost conductor layer with the insulating film interposed in between. The field plate is in contact with the outermost well region and is in contact with the first conductor layer. The outer side end of the field plate extends outwardly beyond an outer side end of the innermost conductor layer.

Abstract: A p-n junction is formed at the interface of a low-concentration n-type impurity layer and a p-type diffusion region in the vicinity of the upper major surface of an n-type semiconductor substrate of a semiconductor device. A mask composed of an absorber is placed on the upper major surface of the semiconductor device, and electron beams are radiated. Thereafter, heat treatment is conducted. As a result, the peak of the crystal lattice defect densities is present in the vicinity of the upper major surface of the n-type semiconductor substrate, and the crystal lattice defect densities are decreasingly distributed toward the lower major surface. Thereby, a semiconductor device that can minimize the variation of the breakdown voltage characteristics of the p-n junction of the diode, and can control the optimum carrier lifetime can be obtained.

Abstract: A semiconductor device is provided. On one main surface side of an n-type semiconductor substrate, a p-type diffusion region to serve as an anode of a diode is formed. A guard ring formed of a p-type diffusion region is formed to surround the anode. On the other main surface side, an n-type ultrahigh-concentration impurity layer and an n-type high-concentration impurity layer to serve as a cathode are formed. In a guard-ring opposed region located in the cathode and opposite to the guard ring, a cathode-side p-type diffusion region is formed. Accordingly, concentration of the electric current on an outer peripheral end portion of the anode is suppressed.

Abstract: A semiconductor device has an active portion having at least one well region in a semiconductor layer, and a breakdown voltage maintaining structure surrounding the active portion. The maintaining structure includes a conductor layer over each of a plurality of guard rings with an insulating film interposed in between and connected to the respective guard ring. An inner side end portion of each conductor layer projects over the immediate adjacent inner side guard ring. The impurity concentration of the guard rings is set between the impurity concentrations of the semiconductor layer and the well regions. A field plate can extend over the innermost conductor layer with the insulating film interposed in between. The field plate is in contact with the outermost well region and is in contact with the first conductor layer. The outer side end of the field plate extends outwardly beyond an outer side end of the innermost conductor layer.

Abstract: The superjunction semiconductor device includes a drain drift section, which includes a first alternating conductivity type layer formed of first n-type regions and first p-type regions arranged alternately. The device also includes a peripheral section around the drain drift section, which includes a second alternating conductivity type layer formed of second n-type regions and second p-type regions arranged alternately. The peripheral section further includes a third alternating conductivity type layer in its surface portion. The third alternating conductivity type layer is formed of third n-type regions and third p-type regions arranged alternately. At least the peripheral section is configured to improve the avalanche withstanding capability over the entire device.

Abstract: A p-n junction is formed at the interface of a low-concentration n-type impurity layer 3 and a p-type diffusion region 5 in the vicinity of the upper major surface of an n-type semiconductor substrate 2 of a semiconductor device 1. A mask 15 composed of an absorber is placed on the upper major surface of the semiconductor device 1, and electron beams are radiated. Thereafter, heat treatment is conducted. As a result, the peak of the crystal lattice defect densities is present in the vicinity of the upper major surface of the n-type semiconductor substrate 2, and the crystal lattice defect densities are decreasingly distributed toward the lower major surface. Thereby, a semiconductor device that can minimize the variation of the breakdown voltage characteristics of the p-n junction of the diode, and can control the optimum carrier lifetime can be obtained.

Abstract: The superjunction semiconductor device includes a drain drift section, which includes a first alternating conductivity type layer formed of first n-type regions and first p-type regions arranged alternately. The device also includes a peripheral section around the drain drift section, which includes a second alternating conductivity type layer formed of second n-type regions and second p-type regions arranged alternately. The peripheral section further includes a third alternating conductivity type layer in its surface portion. The third alternating conductivity type layer is formed of third n-type regions and third p-type regions arranged alternately. At least the peripheral section is configured to improve the avalanche withstanding capability over the entire device.

Abstract: To provide an atomic force microscopy which allows the measurement of the configuration of a surface being measured by using the phenomenon observed between the surface being measured and a probe approaching thereto at very fine distance. By selecting the material of the tip surface of said probe such that the surface energy of said probe tip becomes less than the interface energy between the tip surface and the surface being measured, thereby the surface configuration of soft body, or soft fouling adhered to the body surface can be measured. A method of measuring the surface configuration and a method of producing magnetic recording medium using the same are also provided.

Abstract: A vertical MOS semiconductor device exhibits a high breakdown voltage and low on-resistance, reduces the tradeoff relation between the on-resistance and the breakdown voltage, and realizes high speed switching. The semiconductor device has a breakdown-voltage sustaining layer, such as an n?-type drift layer, and a well region, such as a p-type well region, in the breakdown-voltage sustaining layer. The resistivity ? (?cm) of the breakdown-voltage layer is within a range expressed in terms of the breakdown voltage Vbr (V). The semiconductor device also has stripe shaped surface drain regions that extend from the well region and are surrounded by the well region. The surface area ratio between surface drain regions and the well region, which includes the source region, is from 0.01 to 0.2.

Abstract: A MOS semiconductor device includes n?-type surface regions, which are extended portions of an n?-type drift layer 12 extended to the surface of the semiconductor chip. Each n?-type surface region 14 is shaped with a stripe surrounded by a p-type well region. The surface area ratio between n?-type surface regions 14 and p-type well region 13 including an n+-type region 15 is from 0.01 to 0.2. The MOS semiconductor device further includes, in the breakdown withstanding region thereof, a plurality of guard rings, the number of which is equal to or more than the number n calculated from the following equation n=(Breakdown voltage Vbr (V))/100, and the spacing between the adjacent guard rings is set at 1 ?m or less.

Abstract: A MOS semiconductor device includes n?-type surface regions, which are extended portions of an n?-type drift layer 12 extended to the surface of the semiconductor chip. Each n?-type surface region 14 is shaped with a stripe surrounded by a p-type well region. The surface area ratio between n?-type surface regions 14 and p-type well region 13 including an n+-type region 15 is from 0.01 to 0.2. The MOS semiconductor device further includes, in the breakdown withstanding region thereof, a plurality of guard rings, the number of which is equal to or more than the number n calculated from the following equation n=(Breakdown voltage Vbr (V))/100, and the spacing between the adjacent guard rings is set at 1 ?m or less.

Abstract: A MOS semiconductor device includes n−-type surface regions, which are extended portions of an n−-type drift layer 12 extended to the surface of the semiconductor chip. Each n−-type surface region 14 is shaped with a stripe surrounded by a p-type well region. The surface area ratio between n−-type surface regions 14 and p-type well region 13 including an n+-type region 15 is from 0.01 to 0.2. The MOS semiconductor device further includes, in the breakdown withstanding region thereof, a plurality of guard rings, the number of which is equal to or more than the number n calculated from the following equation n=(Breakdown voltage Vbr (V))/100, and the spacing between the adjacent guard rings is set at 1 &mgr;m or less.

Abstract: To provide an atomic force microscopy which allows the measurement of the configuration of a surface being measured by using the phenomenon observed between the surface being measured and a probe approaching thereto at very fine distance.

Abstract: To facilitate the mounting and removing an automotive air bag system to and from a vehicle body, the air bag system comprises a detachable hinge formed between a part of the air bag housing and a fixed member of a vehicle body, and a releasable latch device provided in the housing. The latch device is adapted to latch onto a striker member integrally formed in the fixed member in a detachable manner. Thus, the mounting of the air bag system can be easily accomplished by first engaging the hinge, and then latching the latch device onto the striker member. The removal of the air bag system can be accomplished equally easily by reversing this process.

Abstract: A MOS semiconductor device includes n−-type surface regions, which are extended portions of an n−-type drift layer 12 extended to the surface of the semiconductor chip. Each n−-type surface region 14 is shaped with a stripe surrounded by a p-type well region. The surface area ratio between n−-type surface regions 14 and p-type well region 13 including an n+-type region 15 is from 0.01 to 0.2. The MOS semiconductor device further includes, in the breakdown withstanding region thereof, a plurality of guard rings, the number of which is equal to or more than the number n calculated from the following equation n=(Breakdown voltage Vbr (V))/100, and the spacing between the adjacent guard rings is set at 1 &mgr;m or less.