Abstract: An LDMOS transistor has a Schottky diode inserted at the center of a doped region of the LDMOS transistor. A Typical LDMOS transistor has a drift region in the center. In this case a Schottky diode is inserted at the center of this drift region which has the effect of providing a Schottky diode connected from source to drain in the forward direction so that the drain voltage is clamped to a voltage that is lower than the PN junction threshold, thereby avoiding forward biasing the PN junction. An alternative is to insert the Schottky diode at the well in which the source is formed, which is on the periphery of the LDMOS transistor. In such case the Schottky diode is formed differently but still is connected from source to drain in the forward direction to achieve the desired voltage clamping at the drain.

Abstract: A chip-scale schottky package which has at least one cathode electrode and at least one anode electrode disposed on only one major surface of a die, and solder bumps connected to the electrode for surface mounting of the package on a circuit board.

Abstract: A semiconductor device including a base layer of a first conductivity type having a first main surface and a second main surface opposite the first main surface, a first main electrode layer connected to the first main surface, control regions arranged inside grooves penetrating the first main electrode layer and reach inside the base layer, and a second main electrode layer of the first conductivity type and connected to the second main surface.

Abstract: A extractor implanted region is used in a silicon-on-insulator CMOS memory device. The extractor region is reversed biased to remove minority carriers from the body region of partially depleted memory cells. This causes the body region to be fully depleted without the adverse floating body effects.

Abstract: In accordance with an embodiment of the invention, a Schottky diode includes a metal layer in contact with a semiconductor region to form a Schottky barrier therebetween. A first trench extends in the semiconductor region. The first trench includes at least one electrode or diode therein.

Abstract: An integrated circuit includes a high voltage Schottky barrier diode and a low voltage device. The Schottky barrier diode includes a lightly doped p-well as guard ring while the low voltage devices are built using standard, more heavily doped p-wells. By using a process including a lightly doped p-well and a standard p-well, high voltage and low voltage devices can be integrated onto the same integrated circuit. In one embodiment, the lightly doped p-well and the standard p-well are formed by performing ion implantation using a first dose to form the lightly doped p-well, masking the lightly doped p-well, and performing ion implantation using a second dose to form the standard p-well. The second dose is the difference of the dopant concentrations of the lightly doped p-well and the standard p-well. In other embodiments, other high voltage devices can also be built by incorporating the lightly doped p-well structure.

Abstract: There are provided a power switching element including a first semiconductor layer of a first conductivity type; a plurality of second semiconductor layers of a second conductivity type, which are in a columnar shape, and arranged in the first semiconductor layer at certain intervals in a direction parallel to a layer surface of the first semiconductor layer; a first electrode formed on a surface of one side of the first semiconductor layer, the first electrode being electrically connected with the first semiconductor layer; a plurality of third semiconductor layers selectively formed in a surface region of the other side of the first semiconductor layer, the third semiconductor layers being connected to the second semiconductor layers; a fourth semiconductor layer of the first conductivity type selectively formed in a surface region of the third semiconductor layers; second electrodes formed so as to contact surfaces of the third semiconductor layers and the fourth semiconductor layer; and gate electrodes fo

Abstract: A method for producing a semiconductor component with adjacent Schottky (5) and pn (9) junctions positions in a drift area (2, 10) of a semiconductor material. According to the method, a silicon carbide substrate doped with a first doping material of at least 1018 cm?3 is provided, and a silicon carbide layer with a second doping material of the same charge carrier type in the range of 1014 and 1017 cm?3 is homo-epitaxially deposited on the substrate. A third doping material with a complimentary charge carrier is inserted, and structured with the aid of a diffusion and/or ion implantation, on the silicon carbide layer surface that is arranged far from the substrate to form pn junctions. Subsequently the component is subjected to a first temperature treatment between 1400° C. and 1700° C. Following this temperature treatment, a first metal coating is deposited on the implanted surface in order to form a Schottky contact and then a second metal coating is deposited in order to form an ohmic contact.

Abstract: A new low forward voltage drop Schottky barrier diode and its manufacturing method are provided. The method includes steps of providing a substrate, forming plural trenches on the substrate, and forming a metal layer on the substrate having plural trenches thereon to form a barrier metal layer between the substrate and the surface metal layer for forming the Schottky barrier diode.

Abstract: A gate-body cross-linked metal-oxide-semiconductor transistor circuit is provided for use in integrated circuits. The circuit has parallel metal-oxide-semiconductor transistors. The sources of the transistors serve as circuit inputs and the drains of the transistors are tied together to form an output. Complementary control signals are applied to the gates of the transistors, so that one transistor is turned on when the other transistor is turned off. Schottky diodes are used to cross-link the transistors. Each Schottky diode has an anode formed from a transistor body and a cathode connected to a gate.

Abstract: A MOSgated device has spaced vertical trenches lined with a gate oxide and filled with a P type polysilicon gate. The gate oxide extends along a vertical N? channel region disposed between an N+ source region and an N? drift region. A Schottky barrier of aluminum is disposed adjacent the accumulation region extending along the trench to collect holes which are otherwise injected into the source region during voltage blocking. A common source or drain contact is connected to the N+ region and to the Schottky contact. A two gate embodiment is disclosed in which separately energized gates are connected to alternatively located gate polysilicon volumes.

Abstract: A trench gate type semiconductor device has an ON resistance that has been reduced. The device has a drain electrode on one side of the substrate and has a drift region, channel region, source region, and a source electrode on the other side. The channel region is sandwiched between a trench gate region covered with insulating film. Current passes when a positive bias voltage is applied to the trench region, and current is cut off when a negative bias voltage is applied.

Abstract: A method for fabricating a Schottky diode using a shallow trench contact to reduce leakage current in the fabrication of an integrated circuit device is described. An insulating layer is deposited over a thermal oxide layer provided overlying a silicon semiconductor substrate. A contact opening is etched through the insulating layer and the thermal oxide layer to the silicon substrate. The contact opening is overetched whereby a shallow trench is formed within the silicon substrate underlying the contact opening wherein the shallow trench has a bottom and sidewalls comprising the silicon substrate. A first metal layer is deposited over the insulating layer and within the contact opening and within the shallow trench.

Abstract: A high withstand voltage semicnductor device does not show any significant fall of its withstand voltage if the impurity concentration of the RESURF layer of a low impurity concentration semiconductor region thereof varies from the optimal level and/or influenced by the fixed electric charge.

Abstract: A extractor implanted region is used in a silicon-on-insulator CMOS memory device. The extractor region is reversed biased to remove minority carriers from the body region of partially depleted memory cells. This causes the body region to be fully depleted without the adverse floating body effects.

Abstract: To attain reduction in size of a semiconductor device having a power transistor and an SBD, a semiconductor device according to the present invention comprises a first region and a second region formed on a main surface of a semiconductor substrate; plural first conductors and plural second conductors formed in the first and second regions respectively; a first semiconductor region and a second semiconductor region formed between adjacent first conductors in the first region, the second semiconductor region lying in the first semiconductor region and having a conductivity type opposite to that of the first semiconductor region; a third semiconductor region formed between adjacent second conductors in the second region, the third semiconductor region having the same conductivity type as that of the second semiconductor region and being lower in density than the second semiconductor region; a metal formed on the semiconductor substrate in the second region, the third semiconductor region having a metal contact

Abstract: An integrated Schottky barrier diode chip includes a compound semiconductor substrate, a plurality of Schottky barrier diodes formed on the substrate and an insulating region formed on the substrate by an on implantation. The insulating region electrically separates a portion of a diode at a cathode voltage from a portion of the diode at an anode voltage. Because of the absence of a polyimide layer and trench structures, this planar device configuration results in simpler manufacturing method and improved device characteristics.

Abstract: A method of operating a vertical DMOS transistor associated with a Schottky diode, the method including diverting current from flowing through a body-to-drain pn junction diode to flowing through the Schottky diode when a metallic source contact becomes more positive than a drain of the DMOS transistor by forward conduction voltage of the Schottky diode to reduce the amount of source current reaching the substrate and reducing operational characteristics of parasitic devices associated with the integrated circuit.

Abstract: This invention relates to a MOS transistor made in the thin film of silicon of an SOI chip (10), said thin film (13) being slightly doped and of less than 30 nm in thickness, the source (14) and drain (15) contacts being of the Schottky type at the lowest level of Schottky barrier possible for majority carriers, with an accumulation type transistor operation.

Abstract: An integrated circuit having a plurality of trench Schottky barrier rectifiers within one or more rectifier regions and a plurality of trench DMOS transistors within one or more transistor regions.

Abstract: A semiconductor rectifier includes an intermediate semiconductor region (29) extending between anode (9) and cathode (7) contacts. A trenched gate (19) with insulated sidewalls (15) and base (17) can deplete the intermediate region. However, a shield region (23) acts to shield the intermediate region (29) from the gate (19) to allow current to flow in dependence on the polarity of the voltage applied between anode and cathode contacts (9, 7).

Abstract: A technique is provided which makes it possible to reduce the area of a power MOSFET. A power MOSFET 1 according to the invention is a trench type in which a source region 27 is exposed on both of a substrate top surface 51 and an inner circumferential surface 52 of a trench 18. Since this makes it possible to provide contact between the source region 27 and a source electrode film 29 not only on the substrate top surface 51 but also on the inner circumferential surface 52 of the trench 18, source contact is provided with a sufficiently low resistance only on the substrate top surface, and the area of the device can be made smaller than that in the related art in which the source region 27 has been formed in a larger area.

Abstract: The invention concerns a monolithically integrated semiconductor component, having a first charge carrier region (12) of a first charge carrier doping; at least two second charge carrier regions (14) with opposite charge carrier doping, patterned within the first charge carrier region (12) at a spacing from one another; and third charge carrier regions (16), with the first charge carrier doping, patterned within the second charge carrier regions (14), a PN transition (22) being short-circuited between the second charge carrier regions (14) and the third charge carrier regions (16) via a contacting area (20) (source connection), the first charge carrier region (12) being equipped with a contact (18) (drain connection), and the second charge carrier regions (14) being invertable by means of a contacting area (26) in the region between the first charge carrier region (12) and the third charge carrier region (16); and having at least one Schottky diode (30) connected in parallel with the charge carrier region (12

Abstract: A method for fabricating a body contact silicon-on-insulator transistor (10) includes forming a semiconductor substrate (12) over an insulator (14) and lightly doping the semiconductor substrate (12) to form a body region (18). The method also includes forming a gate (20) over the semiconductor substrate (12) and separated from the semiconductor substrate (12) by a gate insulator layer (21). The gate (20) defines a source region (22), a drain region (24) and a contact region (26). The method also includes masking a portion (36) of the gate (20) and the contact region (26) and heavily doping the source region (22), the drain region (24) and an unmasked portion (36) of the gate (20) with a material having a conductivity substantially opposite a conductivity of the body region (18).

Abstract: A diode (20), having first and second conductive layers (24,26), a conductive pad (28), and a distributed reverse surge guard (22), provides increased protection from reverse current surges. The surge guard (22) includes an outer loop (42) of P+-type surge guard material and an inner grid (44) of linear sections (46, 48) which form a plurality of inner loops extending inside the outer loop (42). The surge guard (22) distributes any reverse current over the area of the conductive pad (28) to provide increased protection from transient threats such as electrostatic discharge (ESD) and during electrical testing.

Abstract: A power amplifier system has a high frequency power amplifier circuit section employing source-grounded enhancement type n-channel MESFETs for receiving a drain bias voltage and a gate bias voltage of zero volts or positive low potentials supplied from a unipolar power supply, and amplifying a superposed input signal therewith to output an amplified signal indicative of a change in drain currents. An output matching circuit section applies impedance matching to the amplified signal and outputs the resultant signal. A gate bias voltage circuit section supplies a gate bias voltage to the high frequency power amplifier circuit. When a forward direct current gate voltage is applied to a gate terminal with a source terminal coupled to ground, the DC gate voltage becomes greater than or equal to 0.65 volts, the DC gate voltage causing a gate current value per gate width of 100 micrometers to exceed 100 microamperes.

Abstract: A Schottky rectifier is provided. The Schottky rectifier comprises: (a) a semiconductor region having first and second opposing faces, with the semiconductor region comprising a cathode region of first conductivity type adjacent the first face and a drift region of the first conductivity type adjacent the second face, and with the drift region having a lower net doping concentration than that of the cathode region; (b) one or more trenches extending from the second face into the semiconductor region and defining one or more mesas within the semiconductor region; (c) an insulating region adjacent the semiconductor region in lower portions of the trench; (d) and an anode electrode that is (i) adjacent to and forms a Schottky rectifying contact with the semiconductor at the second face, (ii) adjacent to and forms a Schottky rectifying contact with the semiconductor region within upper portions of the trench and (iii) adjacent to the insulating region within the lower portions of the trench.

Abstract: A Schottky barrier field effect transistor has a gate electrode formed with a field plate in order to achieve a high withstanding voltage, where the thickness of the dielectric layer between the channel layer and the field plate, the distance between the Schottky contact and the drain and the length of the field plate falls within the range of 300 nanometers to 600 nanometers thick, the range from 800 nanometers to 3000 nanometers long and the range of the distance between the Schottky contact and the drain is plus or minus 400 nanometers, respectively, so that the distortion and the return-loss are improved without sacrifice of the withstanding voltage.

Abstract: Semiconductor devices formed in fully or partially compensated semiconductor, (substrate or epi-layer), including minimal current flow voltage switching devices with at least one junction which is rectifying when the semiconductor is caused to be N or P-type by the presence of applied gate voltage field induced carriers, such as inverting and non-inverting gate voltage channel induced semiconductor single devices with operating characteristics similar to conventional multiple device CMOS systems.

Abstract: In a SiC substrate (10), a first active region (12) composed of n-type heavily doped layers (12a) and undoped layers (12b), which are alternately stacked, and a second active region (13) composed of p-type heavily doped layers (13a) and undoped layers (13b), which are alternately stacked, are provided upwardly in this order. A Schottky diode (20) and a pMOSFET (30) are provided on the first active region (12). An nMOSFET (40), a capacitor (50), and an inductor (60) are provided on the second active region (13). The Schottky diode (20) and the MOSFETs (30, 40) have a breakdown voltage characteristic and a carrier flow characteristic due to a multilayer structure composed of &dgr;-doped layers and undoped layers and are integrated in a common substrate.

Abstract: A Schottky barrier diode has a Schottky contact region formed in an n epitaxial layer disposed on a GaAs substrate and an ohmic electrode surrounding the Schottky contact region. The ohmic electrode is disposed directly on an impurity-implanted region formed on the substrate. An insulating region is formed through the n epitaxial layer so that an anode bonding pad is isolated form other elements of the device at a cathode voltage. The planar configuration of this device does not include the conventional polyimide layer, and thus has a better high frequency characteristics than conventional devices.

Abstract: Disclosed are semiconductor devices including at least one junction which is rectifying whether the semiconductor is caused to be N or P-type, by the presence of applied gate voltage field induced carriers in essentially intrinsic, essentially homogeneously simultaneously containing both N and P-type metallurgical dopants at substantially equal doping levels, essentially homogeneously simultaneously containing both N and P-type metallurgical dopants at different doping levels, and containing a single metallurgical doping type, and functional combinations thereof. In particular, inverting and non-inverting gate voltage channel induced semiconductor single devices with operating characteristics similar to conventional multiple device CMOS systems, which can be operated as modulators, are disclosed as are a non-latching SCR and an approach to blocking parasitic currents utilizing material(s) which form rectifying junctions with both N and P-type semiconductor whether metallurigically or field induced.

Abstract: A new low forward voltage drop Schottky barrier diode and its manufacturing method are provided. The method includes steps of providing a substrate, forming plural trenches on the substrate, and forming a metal layer on the substrate having plural trenches thereon to form a barrier metal layer between the substrate and the surface metal layer for forming the Schottky barrier diode.

Abstract: The package size of a diode is made smaller. On the element forming face of a semiconductor substrate having a p−-type conductive type, after a hyper-abrupt p+n+ junction of a p+-type diffusion layer, an n+-type hyper-abrupt layer, an n−-epitaxial layer, an n-type low resistance layer and an n+-type diffusion layer is formed, an anode electrode is formed on the top of the p+-type diffusion layer and a cathode electrode is formed on the top of the n+-type diffusion layer. Thereafter, electrode bumps are formed on the top of the anode electrode and the cathode electrode to thereby manufacture a small diode that can be facedown bonded onto a mounting board.

Abstract: An integrated circuit having a plurality of trench Schottky barrier rectifiers within one or more rectifier regions and a plurality of trench DMOS transistors within one or more transistor regions.

Abstract: An integrated Schottky barrier diode chip includes a compound semiconductor substrate, a plurality of Schottky barrier diodes formed on the substrate and an insulating region formed on the substrate by an on implantation. The insulating region electrically separates a portion of a diode at a cathode voltage from a portion of the diode at an anode voltage. Because of the absence of a polyimide layer and trench structures, this planar device configuration results in simpler manufacturing method and improved device characteristics.

Abstract: A device isolation region made up of a silicon oxide film, which is perfectly isolated up to the direction of the thickness of an SOI silicon layer, and an activation region of the SOI silicon layer, whose only ends are locally thinned, are formed on an SOI substrate. A source diffusion layer and a drain diffusion layer of a MOS field effect transistor in the activation region are provided so that according to the silicidization of the SOI silicon layer subsequent to the formation of a high melting-point metal, a Schottky junction is formed only at each end of the activation region and a PN junction is formed at a portion other than each end thereof.

Abstract: A Schottky barrier diode has a Schottky electrode formed on an operation region of a GaAs substrate and an ohmic electrode surrounding the Schottky electrode. The ohmic electrode is disposed directly on an impurity-implanted region formed on the substrate. A nitride film insulates the ohmic electrode from a wiring layer connected to the Schottky electrode crossing over the ohmic electrode. The planar configuration of this device does not include the conventional polyimide layer, and thus has a better high frequency characteristics than conventional devices.

Abstract: A grooved channel Schottky contacted MOSFET has asymmetric source and drain regions. The MOSFET includes an undoped silicon substrate with a background doping concentration of less than about 1017 cm−3. A grooved channel is formed in a first surface of the substrate. A first metal silicide material is formed in a first side of the grooved channel, forming a source region, and a second metal silicide material is formed on a second side of the grooved channel, forming a drain region. A metal gate is formed in the grooved channel. The grooved structure allows the off-state current to be reduced to less than 50 pA/&mgr;m. Further, the feature size can be scaled down to 10 nm without strong short-channel effects (DIBL<0.063) and the gate delay (CV/I) is reduced to 2.4 ps.

Abstract: The invention relates to a semiconductor component with adjacent Schottky (5) and pn (9) junctions positioned in a drift area (2, 10) of a semiconductor material. The invention also relates to a method for producing said semiconductor component.

Abstract: In some embodiments, a circuit structure comprises a semiconductor substrate, an opening passing through the substrate between a first side of the substrate and a second side of the substrate, and a plurality of conductive layers in the opening. In some embodiments, one conductive layer provides an electromagnetic shield that shields the substrate from AC signals carried by a contact pad made from another conductive layer on a backside of the substrate. The conductive layers can also be used to form capacitor/rectifier networks. Manufacturing methods are also provided.

Abstract: A semiconductor device comprises a first semiconductor layer of a first conductivity type provided on a semiconductor substrate of the first conductivity type, a base layer of a second conductivity type provided in the first semiconductor layer, for defining a vertical MISFET including source regions and a gate electrode on a gate insulation film, a Schottky barrier diode (SBD)-forming region provided in the first semiconductor layer around the base layer, a guard ring region of the second conductivity type provided around SBD-forming region, a first main electrode disposed above the first semiconductor layer and provided in common as both a source electrode of the MISFET and an anode of the SBD, a surface gate electrode disposed above the first semiconductor layer, and a second main electrode provided in common as a drain electrode of the MISFET and a cathode of the SBD.

Abstract: A switching device receives two pairs of balanced signals and outputs one of the two pairs of the signals. The device is composed of two SPDT switches which share two control signals provided to the gates of the FET of the SPDT switches. The package of the device has eight external electrodes on the back side of the package. The eight external electrodes are configured so that they are aligned symmetrically with respect to the center line of the package. The device requires only a small package space and is suitable for mobile communication application such as cell phone accommodating CDMA and GPS signals.

Abstract: An improved Schottky device, having a low resistivity layer of semiconductor material, a high resistivity layer of semiconductor material and a buried dopant region positioned in the high resistivity layer utilized to reduce reverse leakage current. The low resistivity layer can be an N+ material while the high resistivity layer can be an N− layer. The buried dopant region can be of P+ material, thus forming a PN junction with an associated charge depletion zone in the N− layer and an associated low reverse leakage current. The location of the P+ material allows for a full Schottky barrier between the N− material and a barrier metal to be maintained, thus the device experiences a low forward voltage drop.

Abstract: A method of fabricating apparatus, and the apparatus, for providing low voltage temperature compensation in a single power supply HFET including a stack of epitaxially grown compound semiconductor layers with an HFET formed in the stack. A Schottky diode is formed in the stack adjacent the HFET during the formation of the HFET. The HFET and the Schottky diode are formed simultaneously, with a portion of one of the layers of metal forming the gate of the HFET being positioned in contact with a layer of the stack having a low bandgap (e.g. less than 0.8 eV) to provide a turn-on voltage for the Schottky diode of less than 1.8 Volts. The Schottky diode is connected to the gate contact of the HFET by a gate circuit to compensate for changes in current loading in the gate circuit with changes in temperature.

Abstract: An insulating-gate semiconductor device has a first nitride semiconductor layer formed over a substrate and an insulating oxidation layer obtained by oxidizing a second nitride semiconductor layer formed on the first nitride semiconductor layer. A gate electrode is formed on the insulating oxidation layer.

Abstract: An integrated semiconductor circuit device comprising a diode bridge circuit formed of a Schottky barrier diode and a periphery circuit formed of a MOS transistor which are formed on a single silicon substrate, wherein a Schottky barrier, which is a component of the Schottky barrier diode, is made of a silicide layer.

Abstract: On a Schottky tunnel junction with Schottky metal as a source, an extremely thin and a high density impurities semiconductor layer having a conduction type different from that of a high density impurities semiconductor constituting the base junction is formed, and height and width of this extremely thin high density impurities semiconductor layer are controlled by adjusting a voltage loaded to a MOS gate formed on this tunnel junction section, so that a main portion of the drain current comprises a carrier passing through the barrier because of the tunnel effect and a carrier moving over this barrier. In addition, a CMOS structure is made to prepare a three-dimensionally or three-dimensionally integrated circuit.

Abstract: An edge termination for a semiconductor component containing a semiconductor body formed of silicon carbide. The edge termination has at least one diode chain that is insulated from the semiconductor body and provided with a plurality of semiconductor layers having alternating conductivity types.

Abstract: Disclosed are semiconductor devices including at least one junction which is rectifying whether the semiconductor is caused to be N or P-type, by the presence of field induced carriers. In particular, inverting and non-inverting gate voltage channel induced semiconductor single devices with operating characteristics similar to conventional multiple device CMOS systems, which can be operated as modulators, are disclosed as are a non-latching SCR and an approach to blocking parasitic currents. Operation of the gate voltage channel induced semiconductor single devices with operating characteristics similar to multiple device CMOS systems under typical bias schemes is described, and simple demonstrative five mask fabrication procedures for the inverting and non-inverting gate voltage channel induced semiconductor single devices with operating characteristics similar to multiple device CMOS systems are also presented.