Abstract: According to one embodiment, a semiconductor memory device includes an insulating film with a recess formed in an upper surface, and a conductive film provided on the insulating film and containing silicon, carbon and an impurity serving as an acceptor or donor for silicon. Carbon concentration of a first portion of the conductive film in contact with the insulating film is lower than carbon concentration of a second portion of the conductive film located in the recess and being equidistant from the insulating film placed on both sides thereof.

Abstract: A device has a microelectromechanical system (MEMS) component with at least one surface and a coating disposed on at least a portion of the surface. The coating has a compound of the formula M(CnF2n+1Or), wherein M is a polar head group and wherein n?2r. The value of n may range from 2 to about 20, and the value of r may range from 1 to about 10. The value of n plus r may range from 3 to about 30, and a ratio of n:r may have a value of about 2:1 to about 20:1.

Abstract: A semiconductor device includes an oxide semiconductor layer, a source electrode and a drain electrode electrically connected to the oxide semiconductor layer, a gate insulating layer covering the oxide semiconductor layer, the source electrode, and the drain electrode, and a gate electrode over the gate insulating layer. The source electrode and the drain electrode include an oxide region formed by oxidizing a side surface thereof. Note that the oxide region of the source electrode and the drain electrode is preferably formed by plasma treatment with a high frequency power of 300 MHz to 300 GHz and a mixed gas of oxygen and argon.

Abstract: A method for depositing one or more materials on a substrate, such as for example, a semiconductor substrate that includes providing the substrate; applying a polymer film to at least a portion of a surface of the substrate; and exposing the semiconductor substrate to a supercritical fluid containing at least one reactant for a time sufficient for the supercritical fluid to swell the polymer and for the at least one reactant to penetrate the polymer film. The reactant is reacted to cause the deposition of the material on at least a portion of the substrate. The substrate is removed from the supercritical fluid, and the polymer film is removed. The process permits the precise deposition of materials without the need for removal of excess material using chemical, physical, or a combination of chemical and physical removal techniques.

Abstract: A method of modulating grain size in a polysilicon layer and devices fabricated with the method. The method includes forming the layer of polysilicon on a substrate; and performing an ion implantation of a polysilicon grain size modulating species into the polysilicon layer such that an average resultant grain size of the implanted polysilicon layer after performing a pre-determined anneal is higher or lower than an average resultant grain size than would be obtained after performing the same pre-determined anneal on the polysilicon layer without a polysilicon grain size modulating species ion implant.

Abstract: A CMOS transistor and a method of manufacturing the CMOS transistor are disclosed. An NMOS transistor is formed on a first region of a semiconductor substrate. A PMOS transistor is formed on a second region of a semiconductor substrate. The NMOS transistor includes a first gate conductive layer. The PMOS transistor includes a second gate conductive layer. The first gate conductive layer includes a metal having a nitrogen concentration increasing in a direction from a lower portion toward an upper portion. In addition, the metal has a work function of about 4.0 eV to about 4.3 eV. The third gate conductive layer includes a metal having a nitrogen concentration increasing in a direction from a lower portion toward an upper portion. In addition, the metal has a work function of about 4.7 eV to about 5.0 eV.

Abstract: Copper diffusion barrier films having low dielectric constants are suitable for a variety of copper/inter-metal dielectric integration schemes. Copper diffusion barrier films in accordance with the invention are composed of one or more layers of silicon carbide, at least one of the silicon carbide layers having a composition of at least 40% carbon (C), for example, between about 45 and 60% carbon (C). The films' high carbon-content layer will have a composition wherein the ratio of C to Si is greater than 2:1; or >3:1; or >4:1; or >5.1. The high carbon-content copper diffusion barrier films have a reduced effective k relative to conventional barrier materials.

Abstract: A high-k dielectric film, a method of forming the high-k dielectric film, and a method of forming a related semiconductor device are provided. The high-k dielectric film includes a bottom layer of metal-silicon-oxynitride having a first nitrogen content and a first silicon content and a top layer of metal-silicon-oxynitride having a second nitrogen content and a second silicon content. The second nitrogen content is higher than the first nitrogen content and the second silicon content is higher than the first silicon content.

Abstract: A method of manufacturing a semiconductor device having an interconnection part formed of multiple carbon nanotubes is disclosed. The method includes the steps of (a) forming a growth mode control layer controlling the growth mode of the carbon nanotubes, (b) forming a catalyst layer on the growth mode control layer, and (c) causing the carbon nanotubes to grow by heating the catalyst layer by thermal CVD so that the carbon nanotubes serve as the interconnection part. The growth mode control layer is formed by sputtering or vacuum deposition in an atmospheric gas, using a metal selected from a group of Ti, Mo, V, Nb, and W. The growth mode is controlled in accordance with a predetermined concentration of oxygen gas of the atmospheric gas.

Abstract: A method of modulating grain size in a polysilicon layer and devices fabricated with the method. The method comprises forming the layer of polysilicon on a substrate; and performing an ion implantation of a polysilicon grain size modulating species into the polysilicon layer such that an average resultant grain size of the implanted polysilicon layer after performing a pre-determined anneal is higher or lower than an average resultant grain size than would be obtained after performing the same pre-determined anneal on the polysilicon layer without a polysilicon grain size modulating species ion implant.

Abstract: A fingerprint detection device has a fingerprint sensor chip and a diamond-like carbon (DLC) film covering the outermost surface of the sensor chip. The DLC film provides sufficient strength and enhanced electrostatic discharge withstand voltage to the fingerprint sensor chip. Thus, the DLC film protects the fingerprint sensor chip without any conventional protective cover. The DLC film is less scratchable and less stainable. Since the fingerprint detection device has no protective cover, the device can be provided in a thin and compact form. In addition, the device has high reliability.

Abstract: Provided are a semiconductor device comprising a semiconductor substrate, a first insulating film formed thereover, interconnects formed over the first insulating film and having copper as a main component, a second insulating film formed over the upper surface and side surfaces of each of the interconnects and over the first insulating film and having a function of suppressing or preventing copper diffusion, and a third insulating film formed over the second insulating film and having a dielectric constant lower than that of the second insulating film; and a method of manufacturing the semiconductor device. This invention makes it possible to improve dielectric breakdown strength between copper interconnects and reduce capacitance between the copper interconnects.

Abstract: A method is provided for processing a substrate including treating a surface of a dielectric layer comprising silicon and carbon by exposing the dielectric layer comprising silicon and carbon to a plasma of an inert gas, and depositing a photoresist on the dielectric layer comprising silicon and carbon. The dielectric layer may comprise a first dielectric layer comprising silicon, carbon, and nitrogen, and a second layer of nitrogen-free silicon and carbon containing material in situ on the first dielectric layer, and a third dielectric layer comprising silicon, oxygen, and carbon on the second dielectric layer.

Abstract: A fingerprint detection device has a fingerprint sensor chip and a diamond-like carbon (DLC) film covering the outermost surface of the sensor chip. The DLC film provides sufficient strength and enhanced electrostatic discharge withstand voltage to the fingerprint sensor chip. Thus, the DLC film protects the fingerprint sensor chip without any conventional protective cover. The DLC film is less scratchable and less stainable. Since the fingerprint detection device has no protective cover, the device can be provided in a thin and compact form. In addition, the device has high reliability.

Abstract: A composite material that consists mainly of ceramic and semi-metal, that is high in thermal conductivity, that is light in weight, and that has high compatibility in coefficient of thermal expansion (CTE) with a semiconductor element and another member comprising ceramic; a member comprising this composite material; and a semiconductor device comprising the member. The composite material has a structure in which the interstices of a three-dimensional network structure comprising ceramic are filled with a semi-metal-containing constituent produced by deposition after melting, has a CTE of 6 ppm/° C. or less, and has a thermal conductivity of 150 W/m·K or more. The semiconductor device comprises the composite material. The composite material can be obtained by filling the pores of a porous body consisting mainly of ceramic with a semi-metal-containing constituent.

Abstract: A method and structure for increasing an electrical resistance of a resistor that is within a semiconductor structure, by oxidizing or nitridizing a fraction of a surface layer of the resistor with oxygen/nitrogen (i.e., oxygen or nitrogen) particles, respectively. The semiconductor structure may include a semiconductor wafer, a semiconductor chip, and an integrated circuit. The method and structure comprises five embodiments. The first embodiment comprises heating an interior of a heating chamber that includes the oxygen/nitrogen particles as gaseous oxygen/nitrogen-comprising molecules (e.g., molecular oxygen/nitrogen). The second embodiment comprises heating the fraction of the surface layer by a beam of radiation (e.g., laser radiation), or a beam of particles, such that the semiconductor structure is within a chamber that includes the oxygen/particles as gaseous oxygen/nitrogen-comprising molecules (e.g., molecular oxygen/nitrogen).

Abstract: A semiconductor device or integrated circuit has high and low resistive contacts. Mobility spoiling ions such as carbon are implanted into all contacts of the substrate. High resistive contacts are temporarily covered with an oxide during processing to prevent silicide from forming due to interaction between a siliciding metal and the implanted mobility spoiling ions in the contacts. The resulting high resistance contacts have highly linear I-V curves, even at high voltages. Selective silicide formation converts some of the contacts back to low resistance contacts as a result of interaction between a siliciding metal and the implanted mobility spoiling ions in the low resistance contacts.

Abstract: A siloxan polymer insulation film has a dielectric constant of 3.3 or lower and has —SiR2O— repeating structural units. The siloxan polymer has dielectric constant, high thermal stability and high humidity-resistance on a semiconductor substrate. The siloxan polymer is formed by directly vaporizing a silicon-containing hydrocarbon compound expressed by the general formula Si&agr;O&bgr;CxHy (&agr;, &bgr;, x, and y are integers) and then introducing the vaporized compound to the reaction chamber of the plasma CVD apparatus. The residence time of the source gas is lengthened by reducing the total flow of the reaction gas, in such a way as to form a siloxan polymer film having a micropore porous structure with low dielectric constant.

Abstract: To improve the gettering performance by ion implanting boron and improves the production yield of the semiconductor device by using an epitaxial wafer of good quality suppressing the occurrence of dislocations. For this purpose, an epitaxial wafer in which an epitaxial layer of about 1 &mgr;m is formed to a CZ semiconductor substrate implanted with boron ions which are dopant and carbon ions which are not a dopant is provided, and transistors are formed on the surface of the epitaxial layer.

Abstract: A semiconductor device is provided and contains a substrate, a first wiring layer, a first oxide film, a dielectric film, a first nitrogen layer, a second wiring layer, a via hole, and a second nitrogen layer. The first wiring layer is formed on the substrate, and the first oxide film formed on the first wiring layer. The dielectric film has a low dielectric constant and is disposed between the first and second wiring layers. The first nitrogen layer contains nitrogen and is formed in the first oxide film. The via hole is formed through the dielectric film and is disposed between the first wiring layer and the second wiring layer for electrically connecting the first wiring layer and the second wiring layer. The second nitrogen layer contains nitrogen and is formed on a side wall of the via hole. Since the first and second nitrogen layers prevent moisture from spreading to various portions of the semiconductor device, leak current between adjacent wirings of the wiring layers is prevented.

Abstract: Methods and apparatus for forming word line stacks comprise forming a thin nitride layer coupled between a bottom silicon layer and a conductor layer. In a further embodiment, a diffusion barrier layer is coupled between the thin nitride layer and the bottom silicon layer. The thin nitride layer is formed by annealing a silicon oxide film in a nitrogen-containing ambient.

Abstract: There is provided a method of fabricating a silicon-on-insulator substrate, including the steps of (a) forming a silicon substrate at a surface thereof with an oxygen-containing region containing oxygen at such a concentration that oxygen is not precipitated in the oxygen-containing region in later mentioned heat treatment, (b) forming a silicon oxide film at a surface of the silicon substrate, (c) implanting hydrogen ions into the silicon substrate through the silicon oxide film, (d) overlapping the silicon substrate and a support substrate each other so that the silicon oxide film makes contact with the support substrate, and (e) applying heat treatment to the thus overlapped silicon substrate and support substrate to thereby separate the silicon substrate into two pieces at a region into which the hydrogen ions have been implanted, one of the two pieces remaining on the silicon oxide film as a silicon-on-insulator active layer.

Abstract: A two-step chlorination/alkylation technique used to introduce alkyl groups, —CnH2n+1 (n=1-6), functionally onto single-crystal, (111)-oriented, n-type Si surfaces. H-terminated Si photoanodes were unstable under illumination in contact with an aqueous 0.35 M K4Fe(CN)6-0.05 MK3Fe(CN)6 electrolyte. Such electrodes displayed low open-circuit voltages and exhibited a pronounced time-dependent deterioration in their current density vs potential characteristics due to anodic oxidation. In contrast, Si surfaces functionalized with —CH3 and —C2H5 groups displayed significant improvements in stability while displaying excellent electrochemical properties when used as photoelectrodes in the aqueous Fe(CN)63−/4− electrolyte.

Abstract: The bipolar transistor of the present invention includes a Si collector buried layer, a first base region made of a SiGeC layer having a high C content, a second base region made of a SiGeC layer having a low C content or a SiGe layer, and a Si cap layer 14 including an emitter region. The C content is less than 0.8% in at least the emitter-side boundary portion of the second base region. This suppresses formation of recombination centers due to a high C content in a depletion layer at the emitter-base junction, and improves electric characteristics such as the gain thanks to reduction in recombination current, while low-voltage driving is maintained.

Abstract: A relatively thick gate oxide film and a relatively thin gate oxide film are formed on a surface of silicon substrate. In a region exactly under the relatively thick gate oxide film, a halogen is added only within a depth range of no more than 2 nm from the main surface of silicon substrate. Thus, a semiconductor device having a dual gate oxide and a method of manufacturing the same can be obtained capable of reducing damage to the substrate through a simplified process.

Abstract: A lateral conduction MOS structure characterized by reduced source resistance and reduced pitch. The structure includes a semiconductor substrate having an epitaxial semiconductor layer thereon, the substrate and epitaxial layer being of the same conductivity type. The structure further includes a source layer and a drain layer, each layer being of a second conductivity type, and a channel layer disposed between the source layer and the drain layer. The channel layer has an oxide layer and a gate disposed thereon. At least one of a wet anisotropic and a reactive ion etching step is performed to define a trench having a maximum width of about from 4-6 microns and a depth that extends well into the substrate. An electrically conductive via is then formed by deposition of metal into the trench to thereby establish a low resistance path between the source and the substrate ground.

Abstract: A manufacturing method produces a semiconductor IC device which can maintain a low power consumption for electronic circuits and form gate-isolation layers of different thicknesses without increasing the manufacturing cost. The semiconductor IC device has gate-isolation layers of different thicknesses on the same semiconductor substrate surface. To form such gate-isolation layers, a silicon dioxide layer is formed in first and second regions. The dopant-concentration is adjusted in silicon dioxide layer that is to have a thickness different from the above silicon dioxide layer thickness in the second region B. A carbon-containing semiconductor layer is selectively formed in either the first region or the second region. Therefore, there is no need for additional steps for forming silicon dioxide layers of different thicknesses in the first region and in the second region.

Abstract: A gate dielectric layer comprising a carbon film aligned to, and continuously covering, the gate electrode. The carbon dielectric film adheres to a wide variety of gate metals and is readily etched using etch processes which do not etch into the gate metal. In a preferred embodiment, the self-aligned carbon gate dielectric is deposited by plasma deposition, followed by deposition of a redundant gate dielectric.

Abstract: To improve the gettering performance by ion implanting boron and improves the production yield of the semiconductor device by using an epitaxial wafer of good quality suppressing the occurrence of dislocations. For this purpose, an epitaxial wafer in which an epitaxial layer of about 1 &mgr;m is formed to a CZ semiconductor substrate implanted with boron ions which are dopant and carbon ions which are not a dopant is provided, and transistors are formed on the surface of the epitaxial layer.

Abstract: Reduction in the short channel effect of a Flash EPROM cell is described. A method includes forming a gate structure on a substrate structure, and performing a nitrogen implant. Further included is performing device doping, wherein the nitrogen implant inhibits diffusion of dopant material into a channel of the cell. A Flash EPROM cell with reduced short channel effect includes a gate region, a drain region, and a source region, the source region and drain region defining a channel region therebetween beneath the gate region. The source region and drain region further have nitrogen implanted therein to reduce lateral diffusion of dopant material into the channel region.

Abstract: A semiconductor device comprising:a silicon substrate having a primary plane;an insulation film formed on the primary plane of the silicon substrate by subjecting the silicon substrate to thermal oxidation in an atmosphere of a gas of N.sub.2 O or a mixing gas of N.sub.2 O and O.sub.2 ; andan electrode formed on the insulation film and having nitrogen and a p-type dopant added therein.

Abstract: An integrated circuit with an intermetal level dielectric (IMD) including an organic-silica hybrid (110) and located between metal lines (104).

Abstract: Diffusion of dopants within the gate of the transistor and/or the source/drain regions can be inhibited by the ion co-implantation of impurities in addition to the ion implantation of the n-type or p-type dopants. Implanting a combination of nitrogen and carbon for p-type devices in addition to the p-type dopants and implanting a combination of nitrogen and fluorine for n-type devices in addition to the n-type dopants, significantly reduces the diffusion of the n-type and p-type dopants. The co-implantation of the additional impurities may be performed before patterning of the polysilicon layer to yield the gate conductors. The impurities may be implanted first, followed by the n-type or p-type dopants. Additional implantation of the impurities may be performed after the patterning of the polysilicon layer in order to reduce dopant diffusion in the source and drain regions.

Abstract: An integrated circuit fabrication method incorporating nitrogen into the polysilicon-dielectric interface in an MOS transistor. A semiconductor substrate having a P-well region and an N-well region is provided. Each well region includes channel regions and source/drain regions. A dielectric layer, preferably a thermal oxide, is formed on an upper surface of the semiconductor substrate. The thermal oxide can be grown in a nitrogen bearing ambient, an O.sub.2 ambient, or an H.sub.2 O ambient. Alternatively, the dielectric may be formed from a deposited oxide. Thereafter, a layer of polysilicon is formed on the dielectric layer and a plurality of "nitrogenated" polysilicon gates is formed on the dielectric layer over the channel regions. In a presently preferred embodiment, nitrogen species are introduced into the polysilicon gates with an ion implantation step. The nitrogen implantation step may alternatively be performed before or after the patterning of the polysilicon layer.

Abstract: A semiconductor substrate having a silicon-on-insulator structure may achieve superior performance by utilizing a low oxygen content monocrystalline silicon thin film layer for device formation. A supporting substrate, which may comprise a transparent material, such as quartz, or which may be silicon, has an insulating film disposed thereover. The insulating film preferably has a lower diffusion coefficient with respect to impurities than the monocrystalline silicon thin film, which is provided thereover. In accordance with this structure, oxygen particles are not introduced into the monocrystalline thin film and the thin film has a low oxygen concentration to maximize the minority carrier lifetime, enhance device performance characteristics, and prevent the occurrence of latch up.

Abstract: A semiconductor device is obtained in which initial breakdown voltage of an insulating film is improved. On a silicon substrate, an insulating film is provided which is not more than 100 .ANG. in thickness. An electrode is provided on the silicon substrate, with the insulating film positioned therebetween. Oxygen concentration in the substrate is set to be not more than 1.times.10.sup.18 atoms/cm.sup.3 by old ASTM value.

Abstract: A gate electrode is made up of a polycrystalline silicon film containing phosphorous as a dopant for determining its conductivity type, a titanium silicide film of the C54 structure, and a tungsten silicide film all of which films are laid one on another in said order.

Abstract: A semiconductor device and a method of fabricating such a semiconductor device in which a silicon nitride film constituting a protective film for ion implantation is used for improving the device structure in order that conversion of a metal film into a silicide for reducing the resistance of a shallow-junction diffused layer may not be prevented by the knock-on phenomenon of oxygen, thereby reduce the fabrication cost. A silicon nitride film, which is used as a protective film for ion implantation into a substrate and a gate polysilicon, is processed into side walls of the gate polysilicon thereby to omit the step of forming side walls by a silicon oxide film. Further, in the case where boron is diffused into the gate polysilicon, boron diffusion is suppressed by nitrogen knock-on, thereby preventing boron from going through the gate oxide film.

Abstract: After formation a gate electrode and source/drain regions, N ions or O ions are implanted into a predetermined region using a resist mask, and a Ti layer is deposited on the entire face of a substrate, and then the Ti layer is silicided in self-alignment by a heat treatment, whereby a high resistivity TixNySiz mixing layer is formed the predetermined region on the gate electrode and the source/drain regions 10, and a low resistivity TiSi.sub.2 layer 12 is formed on another region.

Abstract: According to a method of manufacturing a thin film transistor (TFT), amorphous silicon is formed by ion-implanting either silicon or nitrogen into a region of polysilicon while a region located at the sidewall of a gate electrode is selectively left using the stepped portion of the gate electrode. Then, a heat treatment is applied to convert the amorphous silicon into polysilicon with the remaining polysilicon as a seed crystal. As a result, polysilicon having crystal grains of great grain size can be formed in uniform. Thus, the electric characteristics of a TFT can be improved with no difference in the electric characteristics between each TFT.

Abstract: This invention relates to a semiconductor device comprising at least one p-n junction. The junction is formed from a "p" semiconductor contacting an "n" semiconductor. Said device characterized in that at least one of said "p" or "n" semiconductor is a nanoporous crystalline semiconducting material. These nanoporous materials have an intracrystalline nanopore system whose pores are crystallographically regular and have an average pore diameter of about 2.5 to about 30 .ANG.. Additionally, they have a band gap of greater than 0 to about 5 eV which band gap can be modified by removing a portion of the templating agent from the pore system of the materials. The materials which have these properties include, metal polychalcogenide compounds, metal sulfides and selenides, metal oxides, and metal oxysulfides. These materials can be used in a large variety of semiconducting devices such as light emitting diodes, bipolar transistors, etc. A process for preparing these nanoporous materials is also presented.

Abstract: In order to provide TFTs having a low leak current property in its reverse biased state, the active semiconductor layer of the TFTs is doped with an impurity for increasing the band gap thereof, for example, carbon, nitrogen, and oxygen. Also, in order to compensate the decrease in conductivity due to the addition of the impurities, the source and drain regions are provided with or are by themselves formed with metal silicide layers. Further, these low leak current TFTs formed on a substrate are used as pixel transistors in an electro-optical device while peripheral circuits are formed on the same substrate using high mobility TFTs.

Abstract: A semiconductor device which can effectively prevent impurity diffusion in heat treatment for electrically activating the impurity, and a manufacturing method thereof are disclosed. In the semiconductor device, a diffusion preventing layer having a depth equal to or greater than a junction depth of source/drain regions is formed along the entire junction region of the source/drain regions. The diffusion preventing layer is formed near the surface at the side of a gate insulation layer of the gate electrode including impurity.

Abstract: An overvoltage protection device having multiple shorting dots in the emitter region and multiple buried regions substantially aligned with these shorting dots. The placement, number, and area of these buried regions reduce and more accurately set the overshoot voltage value of the device while maintaining the high surge capacities of the device. Further, doping types and concentrations have been modified from that known in the prior art to reduce overshoot providing a more accurate and sensitive overvoltage protection device than that known previously in the prior art.

Abstract: A method is provided for forming isolated regions of oxide of an integrated circuit, and an integrated circuit formed according to the same. A pad oxide layer is formed over the integrated circuit. A nitrogen doped polysilicon layer is formed over the pad oxide layer. A thick nitride layer is then formed over the nitrogen doped polysilicon layer. An opening is formed in the nitride layer and the nitrogen doped polysilicon layer exposing a portion of the pad oxide layer. The nitrogen doped polysilicon layer is annealed encapsulating the polysilicon layer in silicon nitride. A field oxide region is then formed in the opening.

Abstract: This invention relates to a photodetector including a package having a window disposed in a light incident part, and a light detecting element installed in the package. The light detecting element includes a first region formed of a second conduction-type semiconductor and embedded in a first conduction-type semiconductor layer; a second region formed of second conduction-type semiconductor and embedded so as to be spaced from and to surround the first region; and a conductor layer provided both on at least one part of top surface of the first conduction-type semiconductor layer and on at least one part of top surface of the second region. The first region is surrounded by a second conduction-type second region. On the surface of the semiconductor crystal layer, an electrode is formed on the first region, and a reflection preventing layer is formed on that part of the first region inside the electrode, and a device protecting film is formed on that part of the first region outside the electrode.

Abstract: A thin film transistor including a semiconductor layer including a non-single crystalline silicon layer formed on an insulating surface of a substrate; a gate electrode formed on the semiconductor layer; a gate insulating film disposed between the gate electrode and the semiconductor layer; a source region and a drain region formed in the semiconductor layer; a channel region extending between the source and drain regions in the semiconductor layer, where the source and drain regions have a different conductivity type from the channel region; and an interlayer insulating film covering at least the gate electrode and semiconductor layer except for a contact hole of at least one of the source and drain regions where the contact hole is disposed partially over the source or drain regions; wherein at least one of the source region and said drain region is provided with an electrode through the contact hole, the electrode being contacted with an upper surface of the substrate and an upper surface of one of the sou

Abstract: Between electrodes (9) and (10) are formed a p.sup.+ substrate (2), an n.sup.- epitaxial layer (1) having a protruding portion (3), an n.sup.+ diffusion region (4) and p.sup.+ diffusion regions (13). Control electrodes (6) are formed on insulating films (5) on opposite sides of the protruding portion (3) and n.sup.+ diffusion region (4). The potential at the control electrodes (6) is increased or decreased with the potential at an electrode (10) increased relative to an electrode (9) to generate potential barrier or conductivity modulation in the n.sup.- epitaxial layer (1), whereby a semiconductor device turns off or on. Introduced holes are drawn through the p.sup.+ diffusion regions (13) when the semiconductor device turns off, to provide a small resistance and a short distance when the holes are drawn without changes in the area of the n.sup.+ diffusion region (4). This permits the semiconductor device to have small switching loss and high switching speed with a low ON-voltage.

Abstract: A HEMT type semiconductor device includes a semiconductor substrate, a buffer semiconductor layer formed on the substrate, a first semiconductor well layer formed on the buffer layer and serving as a first conductivity type channel layer, a second semiconductor well layer formed on the first well layer and serving as a second conductivity type opposite the first conductivity, a channel layer and a potential barrier layer formed on the second well layer and forming a potential barrier for carriers. The substrate is made of GaAs or InP, and the layers are successively and epitaxially grown on the substrate. A two dimensional hole gas and a two dimensional electron gas are confined in the first well layer and in the second well layer, respectively.

Abstract: A polysilicon film pattern of a first conductivity type is formed on one main surface of a substrate. A gate electrode is formed on a predetermined region of the pattern with a gate insulating from interposed therebetween. A source region and a drain region, of a second conductivity type are formed in the upper portions of the pattern. These regions are separated by a region of the pattern located under the gate electrode, and are connected to a source electrode and a drain electrode, respectively.