Abstract: A SiC bulk substrate whose top face has been flattened is placed in a vertical thin film growth system to be annealed in an inert gas atmosphere. A material gas of Si is then supplied at a flow rate of 1 mL/min. at a substrate temperature of 1200° C. through 1600° C. Subsequently, the diluent gas is changed to a hydrogen gas at a temperature of 1600° C., and material gases of Si and carbon are supplied with nitrogen intermittently supplied, so as to deposit SiC thin films on the SiC bulk substrate. In a flat ?-doped multilayered structure thus formed, an average height of macro steps formed on the top face and on interfaces therein is 30 nm or less. When the resultant substrate is used, a semiconductor device with a high breakdown voltage and high mobility can be realized.

Abstract: A semiconductor device having an accumulation channel SiC-MISFET structure includes a p-type SiC layer 10 formed on an SiC substrate, an n-type channel layer 20, a gate insulating film 11, a gate electrode 12, and n-type source and drain layers 13a and 13b. The channel layer 20 includes an undoped layer 22 and a ? doped layer 21 which is formed in the vicinity of the lower end of the undoped layer 22. Since the channel layer 20 includes the high-concentration ? doped layer 21 in its deeper portion, the electric field in the surface region of the channel layer is weakened, thereby allowing the current driving force to increase.

Abstract: At least two switching devices each including a substrate formed of a wide bandgap semiconductor, source and gate electrodes formed in a principal surface side of the substrate, and a drain electrode formed on the back surface of the substrate are stacked so that respective upper surface sides of the switching face each other.

Abstract: An active region 30 is formed on a substrate 3, which is made of SiC, GaN, or GaAs, for example, by alternately layering undoped layers 22 with a thickness of for example about 50 nm and n-type doped layers 23 with a thickness (for example, about 10 nm) that is thin enough that quantum effects can be achieved. Carriers spread out into the undoped layers 22 from sub-bands of the n-type doped layers 23 that occur due to quantum effects. In the undoped layers 22, which have a low concentration of impurities, the scattering of impurities is reduced, and therefore a high carrier mobility can be obtained there, and when the entire active region 30 has become depleted, a large withstand voltage value can be obtained due to the undoped layers 22 by taking advantage of the fact that there are no more carriers in the active region 30.

Abstract: A storage-type SiC-MISFET includes a SiC substrate, an n-type drift layer, a p-type well region, an n-type source region, a SiC channel layer which contains an n-type impurity and is to be a storage-type channel layer, a p-type heavily doped contact layer, a gate insulation film, a gate electrode and the like. In the storage-type SiC-MISFET, a partially heavily doped layer is formed by partially implanting ions of a p-type impurity into an upper surface portion of the n-type drift layer and containing an impurity of the same conductive type as that of the impurity implanted into the well region at a higher concentration than that in the well region.

Abstract: Equipment for a communication system has a semiconductor device formed by integrating a Schottky diode, a MOSFET, a capacitor, and an inductor in a SiC substrate. The SiC substrate has a first multilayer portion and a second multilayer portion provided upwardly in this order. The first multilayer portion is composed of ?-doped layers each containing an n-type impurity (nitrogen) at a high concentration and undoped layers which are alternately stacked. The second multilayer portion is composed of ?-doped layers each containing a p-type impurity (aluminum) at a high concentration and undoped layers which are alternately stacked. Carriers in the ?-doped layers spread out extensively to the undoped layers. Because of a low impurity concentration in each of the undoped layers, scattering by impurity ions is reduced so that a low resistance and a high breakdown voltage are obtained.

Abstract: An accumulation-mode MISFET comprises: a high-resistance SiC layer 102 epitaxially grown on a SiC substrate 101; a well region 103; an accumulation channel layer 104 having a multiple ?-doped layer formed on the surface region of the well region 103; a contact region 105; a gate insulating film 108; and a gate electrode 110. The accumulation channel layer 104 has a structure in which undoped layers 104b and ?-doped layers 104a allowing spreading movement of carriers to the undoped layers 104b under a quantum effect are alternately stacked. A source electrode 111 is provided which enters into the accumulation channel layer 104 and the contact region 105 to come into direct contact with the contact region 105. It becomes unnecessary that a source region is formed by ion implantation, leading to reduction in fabrication cost.

Abstract: A Schottky diode includes a semiconductor substrate made of 4H—SiC, an epitaxially grown 4H—SiC layer, an ion implantation layer, a Schottky electrode, an ohmic electrode, and an insulative layer made of a thermal oxide film. The Schottky electrode and the insulative layer are not in contact with each other, with a gap being provided therebetween, whereby an altered layer does not occur. Therefore, it is possible to suppress the occurrence of a leak current.

Abstract: A gate insulating film which is an oxide layer mainly made of SiO2 is formed over a silicon carbide substrate by thermal oxidation, and then, a resultant structure is annealed in an inert gas atmosphere in a chamber. Thereafter, the silicon carbide-oxide layered structure is placed in a chamber which has a vacuum pump and exposed to a reduced pressure NO gas atmosphere at a high temperature higher than 1100° C. and lower than 1250° C., whereby nitrogen is diffused in the gate insulating film. As a result, a gate insulating film which is a V-group element containing oxide layer, the lower part of which includes a high nitrogen concentration region, and the relative dielectric constant of which is 3.0 or higher, is obtained. The interface state density of an interface region between the V-group element containing oxide layer and the silicon carbide layer decreases.

Abstract: P-type active region 12; n-type source/drain regions 13a and 13b; gate insulating film 14 made of a thermal oxide film; gate electrode 15; source/drain electrodes 16a and 16b, are provided over a p-type SiC substrate 11. In the active region 12, p-type heavily doped layers 12a, which are thin enough to create a quantum effect, and thick undoped layers 12b are alternately stacked. When carriers flow, scattering of impurity ions in the active region is reduced, and the channel mobility increases. In the OFF state, a depletion layer expands throughout the active region, and the breakdown voltage increases. As a result of reduction in charges trapped in the gate insulating film or near the interface between the gate insulating film and the active region, the channel mobility further increases.

Abstract: An upper part of a SIC substrate 1 is oxidized at a temperature of 800 to 1400° C., inclusive, in an oxygen atmosphere at 1.4×102 Pa or less, thereby forming a first insulating film 2 which is a thermal oxide film of 20 nm or less in thickness. Thereafter, annealing is performed, and then a first cap layer 3, which is a nitride film of about 5 nm in thickness, is formed thereon by CVD. A second insulating film 4, which is an oxide film of about 130 nm in thickness, is deposited thereon by CVD. A second cap layer 5, which is a nitride film of about 10 nm in thickness, is formed thereon. In this manner, a gate insulating film 6 made of the first insulating film 2 through the second cap layer 5 is formed, thus obtaining a low-loss highly-reliable semiconductor device.

Abstract: Ion implantation is carried out to form a p-well region and a source region in parts of a high resistance SiC layer on a SiC substrate, and a carbon film is deposited over the substrate. With the carbon film deposited over the substrate, annealing for activating the implanted dopant ions is performed, and then the carbon film is removed. Thus, a smooth surface having hardly any surface roughness caused by the annealing is obtained. Furthermore, if a channel layer is epitaxially grown, the surface roughness of the channel layer is smaller than that of the underlying layer. Since the channel layer having a smooth surface is provided, it is possible to obtain a MISFET with a high current drive capability.

Abstract: A semiconductor module comprises independently operable segments 1 (semiconductor elements) on a SiC substrate. Each segment 1 comprises a source electrode pad 2 and a gate electrode pad 3 both provided to the principal surface side of the SiC substrate, and a drain electrode pad provided on the back surface side of the SiC substrate. The semiconductor module further comprises an isolation region such as a trench or a Schottky diode for electrically isolating the adjacent segments 1 from each other. Only electrode pads 2 and 3 of each of the segments 1 determined as conforming items by a test are connected to electrode terminals 41 and 43, respectively.

Abstract: The first basic structure of the electron emission element of the present invention includes at least two electrodes disposed in a horizontal direction at a predetermined interval, and a plurality of electron emission portions made of a particle or an aggregate of the particles dispersively disposed between the electrodes. On the other hand, the second basic structure of the electron emission element of the present invention includes at least two electrodes disposed at a predetermined interval, a conductive layer disposed between the electrodes so as to be electrically connected thereto, and a plurality of electron emission portions made of a particle or an aggregate of the particles dispersively disposed on the surface of the conductive layer between the electrodes.

Abstract: An active region 30 is formed on a substrate 3, which is made of SiC, GaN, or GaAs, for example, by alternately layering undoped layers 22 with a thickness of for example about 50 nm and n-type doped layers 23 with a thickness (for example, about 10 nm) that is thin enough that quantum effects can be achieved. Carriers spread out into the undoped layers 22 from sub-bands of the n-type doped layers 23 that occur due to quantum effects. In the undoped layers 22, which have a low concentration of impurities, the scattering of impurities is reduced, and therefore a high carrier mobility can be obtained there, and when the entire active region 30 has become depleted, a large withstand voltage value can be obtained due to the undoped layers 22 by taking advantage of the fact that there are no more carriers in the active region 30.

Abstract: An inventive semiconductor device is provided with: a silicon carbide substrate 1; an n-type high resistance layer 2; well regions 3 provided in a surface region of the high resistance layer 2; a p+ contact region 4 provided within each well region 3; a source region 5 provided to laterally surround the p+ contact region 4 within each well region 3; first source electrodes 8 provided on the source regions 5 and made of nickel; second source electrodes 9 that cover the first source electrodes 8 and that are made of aluminum; a gate insulating film 6 provided on a portion of the high resistance layer 2 sandwiched between the two well regions 3; a gate electrode 10 made of aluminum; and an interlayer dielectric film 11 that covers the second source electrodes 9 and the gate electrode 10 and that is made of silicon oxide.

Abstract: At least two switching devices each including a substrate formed of a wide bandgap semiconductor, source and gate electrodes formed in a principal surface side of the substrate, and a drain electrode formed on the back surface of the substrate are stacked so that respective upper surface sides of the switching face each other.

Abstract: A storage-type SiC-MISFET includes a SiC substrate, an n-type drift layer, a p-type well region, an n-type source region, a SiC channel layer which contains an n-type impurity and is to be a storage-type channel layer, a p-type heavily doped contact layer, a gate insulation film, a gate electrode and the like. In the storage-type SiC-MISFET, a partially heavily doped layer is formed by partially implanting ions of a p-type impurity into an upper surface portion of the n-type drift layer and containing an impurity of the same conductive type as that of the impurity implanted into the well region at a higher concentration than that in the well region.

Abstract: A semiconductor device having an accumulation channel SiC-MISFET structure includes a p-type SiC layer 10 formed on an SiC substrate, an n-type channel layer 20, a gate insulating film 11, a gate electrode 12, and n-type source and drain layers 13a and 13b. The channel layer 20 includes an undoped layer 22 and a &dgr; doped layer 21 which is formed in the vicinity of the lower end of the undoped layer 22. Since the channel layer 20 includes the high-concentration &dgr; doped layer 21 in its deeper portion, the electric field in the surface region of the channel layer is weakened, thereby allowing the current driving force to increase.

Abstract: An electron emission element includes a substrate, a cathode electrode formed on the substrate, an anode electrode disposed so as to be opposed to the cathode electrode, an electron emission member disposed on the cathode electrode, a control electrode disposed between the cathode electrode and the anode electrode, and an insulating layer. The electron emission member includes a first member having a hole and a second member filling the hole, wherein the second member is more likely to emit electrons than the first member.