Abstract: A method and structure for a voltage converter including a trench field effect transistor (FET) and a trench guarded Schottky diode which is integrated with the trench FET. In an embodiment, a voltage converter can include a lateral FET, a trench FET, and a trench guarded Schottky diode integrated with the trench FET. A method to form a voltage converter can include the formation of a trench FET gate, a trench guarded Schottky diode gate, and a lateral FET gate using a single conductive layer such as a polysilicon layer.

Abstract: A semiconductor device including a substrate, a first device, a second device and an interlayer dielectric layer is provided. The substrate has a first area and a second area. The first device is disposed in the first area of the substrate and includes a first dielectric layer on the substrate and a metal gate on the first dielectric layer. The second device is in the second area of the substrate and includes a second dielectric layer on the substrate and, a polysilicon layer on the second dielectric layer. It is noted that the height of the polysilicon layer is less than that of the metal gate of the first device. The interlayer dielectric layer covers the second device.

Abstract: A circuit is proposed for limiting maximum switching FET drain-source voltage (VDS) of a transformer-coupled push pull power converter with maximum DC supply voltage VIN—MAX. Maximum VDS is accentuated by leakage inductances of the push pull transformer and the power converter circuit traces. The limiting circuit bridges the drains of the switching FETs and it includes two serially connected opposing Zener diodes each having a Zener voltage Vzx. The invention is applicable to both N-channel and P-channel FETs. In a specific embodiment, Vzx is selected to be slightly ?2*VIN—MAX with the maximum VDS clamped to about VIN—MAX+½Vzx, In another embodiment, a proposed power switching device with integrated VDS-clamping includes: a) A switching FET. b) A Zener diode having a first terminal and a second terminal, the second terminal of the Zener diode is connected to the drain terminal of the switching FET.

Abstract: A semiconductor device includes a substrate having a first region and a second region. The first region is electrically isolated from the second region. The semiconductor device further includes a lateral field-effect transistor (FET) disposed within the first region. The lateral FET includes a first terminal and a second terminal. The semiconductor device further includes a diode disposed within the second region, the diode including a plurality of anode regions and a plurality of cathode regions. The semiconductor device further includes a first electrical connection between the first terminal of the lateral FET and the anode regions of the diode, and a second electrical connection between the second terminal of the lateral FET and the cathode regions of the diode. The first and second electrical connections are disposed over a surface of the substrate.

Abstract: In a semiconductor integrated circuit device, testing pads (209b) using a conductive layer, such as relocation wiring layers (205) are provided just above or in the neighborhood of terminals like bonding pads (202b) used only for probe inspection at which bump electrodes (208) are not provided. Similar testing pads may be provided even with respect to terminals like bonding pads provided with bump electrodes. A probe test is executed by using these testing pads or under the combined use of under bump metallurgies antecedent to the formation of the bump electrodes together with the testing pads. According to the above, bump electrodes for pads dedicated for probe testing may not be added owing to the use of the testing pads. Further, the use of testing pads provided in the neighborhood of the terminals like the bonding pads and smaller in size than the under bump metallurgies enables a probe test to be executed after a relocation wiring process.

Abstract: A semiconductor device includes a gate electrode on a gate insulating film over a semiconductor substrate, a first sidewall insulating film on a side surface of the gate electrode, and source and drain regions, each including a pocket diffusion layer of a first conductivity type, and first and second diffusion layers of a second conductivity type. The pocket diffusion layer is disposed in the semiconductor substrate. The first diffusion layer of a second conductivity type extends over the pocket diffusion layer. The first diffusion layer faces toward the gate electrode through the first sidewall insulating film. The second diffusion layer over the first diffusion layer is higher in impurity concentration than the first diffusion layer. The second diffusion layer is separated by the first diffusion layer from the pocket diffusion layer, and has a side surface which faces toward the first sidewall insulating film through the first diffusion layer.

Abstract: This invention discloses a semiconductor power device that includes an active cell area having a plurality of power transistor cells. Each of said power transistor cells has a planar Schottky diode that includes a Schottky junction barrier metal covering areas above gaps between separated body regions between two adjacent power transistor cells. The separated body regions further provide a function of adjusting a leakage current of said Schottky diode in each of said power transistor cells. Each of the planar Schottky diodes further includes a Shannon implant region disposed in a gap between the separated body regions of two adjacent power transistor cells for further adjusting a leakage current of said Schottky diode. Each of the power transistor cells further includes heavy body doped regions in the separated body regions next to source regions surrounding said Schottky diode forming a junction barrier Schottky (JBS) pocket region.

Abstract: A semiconductor device includes: a rectifying element; an electrode pad electrically connected to the rectifying element; and a resistance and a depletion transistor arranged between the rectifying element and the electrode pad, and electrically connected to each other. The semiconductor device has a configuration in which the rectifying element, the resistance, the depletion transistor, and the electrode pad are serially connected. The semiconductor device is configured to generate a gate potential of the depletion transistor based on a difference in potential across the resistance and to produce a depletion layer in a channel of the depletion transistor based on the gate potential. As a result, a semiconductor device having reasonably large current at low voltage and small current at high voltage can be obtained.

Abstract: This invention discloses a new trenched vertical semiconductor power device that includes a capacitor formed between a conductive layer covering over an inter-dielectric layer disposed on top of a trenched gate. In a specific embodiment, the trenched vertical semiconductor power device may be a trenched metal oxide semiconductor field effect transistor (MOSFET) power device. The trenched gate is a trenched polysilicon gate and the conductive layer is a second polysilicon layer covering an inter-poly dielectric layer disposed on top of the trenched polysilicon gate. The conductive layer is further connected to a source of the vertical power device.

Abstract: A mask ROM is provided with a plurality of memory cells each including first and second nodes, and a transistor having a source and drain connected to the first and second nodes, respectively. A first memory cell out of the plurality of memory cells further includes a first resistive interconnection which provides an electrical connection between the first and second nodes. The resistance of the first resistive interconnection is adjusted depending on data stored onto the first memory cell.

Abstract: A semiconductor device includes a power supply line supplied with a power supply voltage; a power supply node connected with the power supply line; a ground line; a ground pad connected with the ground line; a signal input pad; a main protection circuit section configured to discharge an ESD surge applied to a first pad as one of the power supply node, the signal input pad and the ground pad to a second pad as another thereof; a protection object circuit; a connection node connected with the protection object circuit; a first resistance element connected between the signal input pad and the connection node; and a sub protection circuit section.

Abstract: In one embodiment the present invention includes a semiconductor device. The semiconductor device comprises a first semiconductor region, a second semiconductor region and a trench region. The first semiconductor region is of a first conductivity type and a first conductivity concentration. The trench region includes a metal layer in contact with the first semiconductor region to form a metal-semiconductor junction. The second semiconductor region is adjacent to the first semiconductor region that has a second conductivity type and a second conductivity concentration. The second semiconductor region forms a PN junction with the first semiconductor region, and the trench region has a depth such that the metal-semiconductor junction is proximate to the PN junction.

Abstract: A semiconductor device includes an active region defined by an isolation region formed in a cell area, buried gates disposed in the active region and the isolation region, conduction layers disposed on the active region and having the same heights as an surface of the isolation region, and a line type storage node contact connected with one of the conduction layers.

Abstract: A lateral super junction JFET is formed from stacked alternating P type and N type semiconductor layers over a P-epi layer supported on an N+ substrate. An N+ drain column extends down through the super junction structure and the P-epi to connect to the N+ substrate to make the device a bottom drain device. N+ source column and P+ gate column extend through the super junction but stop at the P-epi layer. A gate-drain avalanche clamp diode is formed from the bottom the P+ gate column through the P-epi to the N+ drain substrate.

Abstract: A semiconductor device including a MISFET formed in a well at a main surface of a substrate, a second MISFET formed at a main surface of the substrate, and a passive element formed over the main surface of the substrate and having two terminals. A conductive film is formed at a rear face of the semiconductor substrate. The conductive film is connected with a fixed potential and also electrically connected with the conductive film.

Abstract: This invention discloses configurations and methods to manufacture lateral power device including a super junction structure with an avalanche clamp diode formed between the drain and the gate. The lateral super-junction structure reduces on-resistance, while the structural enhancements, including an avalanche clamping diode and an N buffer region, increase the breakdown voltage between substrate and drain and improve unclamped inductive switching (UIS) performance.

Abstract: A semiconductor memory device includes a substrate of a first impurity type, a first well region of a second impurity type in the substrate, the second impurity type being different from the first impurity type, a second well region of the first impurity type in the substrate, a patterned first dielectric layer on the substrate extending over the first and second well regions, a patterned first gate structure on the patterned first dielectric layer, a patterned second dielectric layer on the patterned first gate structure, and a patterned second gate structure on the patterned second dielectric layer. The patterned first gate structure may include a first section extending in a first direction and a second section extending in a second direction orthogonal to the first section, wherein the first section and the second section intersects each other in a cross pattern.

Abstract: A semiconductor device includes a first insulating film, paired resistance elements each of which includes a first conductive film formed on the first insulating film, a second insulating film formed on the first conductive film and a second conductive film formed on the second insulating film, paired first contact plugs formed on one of the resistance elements and arranged along a first direction, and paired second contact plugs formed on the other resistance. One of the resistance elements has a first width in a second direction perpendicular to the first direction, and a semiconductor region surrounded by an element isolation region has a second width. The first width is smaller than half of the second width. The second insulating films are spaced from each other by a first distance. The second conductive films are spaced from each other by a second distance. The second distance is longer than the first distance.

Abstract: A substrate for a semiconductor device includes a substrate; a transistor disposed on the substrate and including a semiconductor layer, a first insulating film provided in the form of islands so as to at least partly overlap with the semiconductor layer in plan view on the substrate, and a gate electrode disposed so as to face the semiconductor layer with the first insulating film therebetween; and a second insulating film that is disposed on the substrate as substantially the same film as the first insulating film and that is formed in the form of islands so that at least one of the material and the thickness of the second insulating film is different from that of the first insulating film.

Abstract: A semiconductor device includes a substrate with one or more active regions and an isolation layer formed to surround an active region and to extend deeper into the substrate than the one or more active regions. The semiconductor further includes a gate electrode, which covers a portion of the active region, and which has one end ;portion thereof extending over the isolation layer.

Abstract: A capacitor structure includes a semiconductor substrate; a first capacitor plate positioned on the semiconductor substrate, the first capacitor plate including a polysilicon structure having a surrounding spacer; a silicide layer formed in a first portion of an upper surface of the first capacitor plate; a capacitor dielectric layer formed over a second portion of the upper surface of the first capacitor plate and extending laterally beyond the spacer to contact the semiconductor substrate; a contact in an interlayer dielectric (ILD), the contact contacting the silicide layer and a first metal layer over the ILD; and a second capacitor plate over the capacitor dielectric layer, wherein a metal-insulator-metal (MIM) capacitor is formed by the first capacitor plate, the capacitor dielectric layer and the second capacitor plate and a metal-insulator-semiconductor (MIS) capacitor is formed by the second capacitor plate, the capacitor dielectric layer and the semiconductor substrate.

Abstract: The present invention provides a method of controlling bias in an electrical device including providing semiconductor devices on a bulk semiconductor substrate each including an active body region that is isolated from the active body region of adjacent devices, and providing a body resistor in electrical contact with the active body region of the bulk semiconductor substrate, wherein the body resistor provides for adjustability of the body potential of the semiconductor devices. In another aspect the present invention provides a semiconductor device including a bulk semiconductor substrate, at least one field effect transistor formed on the bulk semiconductor substrate including an isolated active body region, and a resistor in electrical communication with the isolated active body region.

Abstract: A multi-dielectric film including at least one first dielectric film that is a composite film made of zirconium-hafnium-oxide and at least one second dielectric film that is a metal oxide film made of amorphous metal oxide. Adjacent ones of the dielectric films are made of different materials.

Abstract: An object of the present invention is that the capacitance of MOS capacitors is changed without varying the kind of an impurity (a donor or an acceptor) in a channel formation region, and an n-type MOS capacitor and a p-type MOS capacitor are formed over a same substrate. By changing the offset length between a contact region and a channel formation region, the capacitance of a MOS capacitor can be changed without increasing the number of manufacturing process. Also, an n-type MOS capacitor and a p-type MOS capacitor can be formed over a same substrate only by changing the offset length. In addition, an n-type MOS capacitor and a p-type MOS capacitor can be formed over a same substrate by changing the dose amount of impurity with respect to a channel formation region while fixing the offset length.

Abstract: Provided is a device for analyzing at least one of a generated amount of positive charges, a generated amount of negative charges, and a generated amount of ultraviolet (UV) light. The device includes a substrate on which at least one of a first device configured to detect a variation in threshold voltage relative to the generated amount of positive charges, a second device configured to detect a variation in threshold voltage relative to the generated amount of negative charges, and a third device configured to detect a variation in threshold voltage relative to the generated amount of UV light is formed.

Abstract: Roughly described, an antenna diode is formed at least partially within the exclusion zone around a TSV, and is connected to the TSV by way of a metal 1 layer conductor at the same time that the TSV is connected to either the gate poly or a diffusion region of one or more transistors placed outside the exclusion zone.

Abstract: A semiconductor device formed on a semiconductor substrate may include a component formed in a contact trench located in an active cell region. The component may comprise a barrier metal deposited on a bottom and portions of sidewalls of the contact trench and a tungsten plug deposited in a remaining portion of the contact trench. The barrier metal may comprise first and second metal layers. The first metal layer may be proximate to the sidewall and the bottom of the contact trench. The first metal layer may include a nitride. The second metal layer may be between the first metal layer and the tungsten plug and between the tungsten plug and the sidewall. The second metal layer covers portions of the sidewalls of not covered by the first metal layer.

Abstract: A FET device for synchronous rectification of the present invention, a FET having no body diode, the characteristics have gate minimization threshold voltage equal or over load voltage, can be achieve FET turn on, and gate minimization threshold voltage under load voltage, can be achieve FET turn off.

Abstract: A transistor component and method of forming a transistor component. One embodiment provides a semiconductor arrangement including a semiconductor body having a at least one first trench, a first field electrode arranged in the lower trench section of the at least one first trench and being insulated from the semiconductor body by a field electrode dielectric. A dielectric layer is formed on the first field electrode in the at least one first trench, including depositing a dielectric material on a first side of the semiconductor body and on the field plate at a higher deposition rate than on sidewalls of the at least one first trench.

Abstract: A high-frequency power amplifier of the type to be mounted in an RF module for mobile phones having high-frequency power field effect transistors and gate protective diodes which are coupled between the gates and the sources of the high-frequency power field effect transistors. The gate protective diodes have an n type region formed over the main surface of a p type epitaxial layer, a first p type region formed at the center of the main surface of the n type region, a second p type region formed over the main surface of the epitaxial layer around the n type region from the periphery of the main surface of the n type region, and p+ type buried layers for coupling the second p type region to a substrate body. The distance between the end portions of the p+ type buried layers and the n+ type region is 7 ?m or more.

Abstract: A power semiconductor device with drain voltage protection includes a semiconductor substrate, at least a trench gate transistor device and at least a trench ESD protection device. An upper surface of the semiconductor substrate has a first trench and a second trench. The trench gate transistor device is disposed in the first trench and the semiconductor substrate. The trench ESD protection device is disposed in the second trench, and includes a first doped region, a second doped region and a third doped region. The first doped region and the third doped region are respectively electrically connected to a drain and a gate of the trench gate transistor device.

Abstract: A semiconductor device having a resistor and a method of fabricating the same are provided. The semiconductor device includes a semiconductor substrate having a first circuit region and a second circuit region. A lower interlayer insulating layer is provided over the semiconductor substrate. A first hole passing through the lower interlayer insulating layer in the first circuit region and a second hole passing through the lower interlayer insulating layer in the second circuit region are provided. A first semiconductor pattern and a second semiconductor pattern are sequentially stacked in the first hole. A first resistor having the same crystalline structure as the second semiconductor pattern is provided in the second hole.

Abstract: Radiation hardened NMOS devices suitable for application in NMOS, CMOS, or BiCMOS integrated circuits, and methods for fabricating them. A device includes a p-type silicon substrate, a field oxide surrounding a moat region on the substrate tapering through a bird's beak region to a gate oxide within the moat region, a heavily-doped p-type guard region underlying at least a portion of the bird's beak region and terminating at the inner edge of the bird's beak region, a gate crossing the moat region, and n-type source and drain regions spaced by a gap from the inner edge of the guard region. A variation of a local oxidation of silicon process is used with an additional bird's beak implantation mask as well as minor alterations to the conventional moat and n-type source/drain masks. The resulting devices have improved radiation tolerance while having a high breakdown voltage and minimal impact on circuit density.

Abstract: A semiconductor memory device according to an embodiment of the present invention includes a resistance element which is constructed with a first conductor which extends in a first direction and is connected to a first contact; a second conductor which extends in said first direction and is connected to a second contact; and a first insulation film which exists between said first conductor and said second conductor, said first insulation film also having an opening in which a third conductor which connects said first conductor and said second conductor is arranged.

Abstract: A gate controlled fin resistance element for use as an electrostatic discharge (ESD) protection element in an electrical circuit has a fin structure having a first connection region, a second connection region and a channel region formed between the first and second connection regions. Furthermore, the fin resistance element has a gate region formed at least over a part of the surface of the channel region. The gate region is electrically coupled to a gate control device, which gate control device controls an electrical potential applied to the gate region in such a way that the gate controlled fin resistance element has a high electrical resistance during a first operating state of the electrical circuit and a lower electrical resistance during a second operating state, which is characterized by the occurrence of an ESD event.

Abstract: In a replacement gate approach, the polysilicon material may be efficiently removed during a wet chemical etch process, while the semiconductor material in the resistive structures may be substantially preserved. For this purpose, a species such as xenon may be incorporated into the semiconductor material of the resistive structure, thereby imparting a significantly increased etch resistivity to the semiconductor material. The xenon may be incorporated at any appropriate manufacturing stage.

Abstract: A resistor is disclosed. The resistor is disposed on a substrate, in which the resistor includes: a dielectric layer disposed on the substrate; a polysilicon structure disposed on the dielectric layer; two primary resistance structures disposed on the dielectric layer and at two ends of the polysilicon structure; and a plurality of secondary resistance structures disposed on the dielectric layer and interlaced with the polysilicon structures.

Abstract: It is an object of the present invention to surely protect a predetermined semiconductor element or a predetermined semiconductor element group in an analog block from a noise generated from a digital block. A semiconductor device according to the present invention includes a semiconductor substrate, a digital block to be a region in which a digital circuit is formed and an analog block to be a region in which an analog circuit is formed, arranged by separating an upper surface of the semiconductor substrate and a substrate potential fixing region provided on the semiconductor substrate so as to surround in a planar view the predetermined semiconductor element group in the analog block, and a pad connected to the substrate potential fixing region and receiving a predetermined potential from an external part.

Abstract: A floorplan for a die having three high-voltage transistors for power applications is described. The three high-voltage transistors are specifically placed in relation to each other to optimize operation.

Abstract: In one embodiment, a junction field effect transistor having a substrate, wherein formed on the substrate is a graded n-doped region having a high doping concentration in an inner region and a low doping concentration in an outer region, with a p-doped buried region adjacent to the graded n-doped region near the outer region, and a spiral resistor connected to the graded n-doped region at its inner region and at its outer region. An ohmic contact at the inner region provides the drain, an ohmic contact at the outer region provides the source, and an ohmic contact at the substrate provides the gate.

Abstract: The present invention provides a semiconductor structure including a buried resistor with improved control, in which the resistor is fabricated in a region of a semiconductor substrate beneath a well region that is also present in the substrate. In accordance with the present invention, the inventive structure includes a semiconductor substrate containing at least a well region; and a buried resistor located in a region of the semiconductor substrate that is beneath said well region. The present invention also provides a method of fabricating such a structure in which a deep ion implantation process is used to form the buried resistor and a shallower ion implantation process is used in forming the well region.

Abstract: A semiconductor device including a metallic compound Hfx1Moy1Nz1 as an electrode. The work function of the electrode can be modulated by doping the metallic compound with dopants including nitrogen, silicon or germanium. The metallic compound of the present invention is applicable to PMOS, NMOS, CMOS transistors and capacitors.

Abstract: A bypass capacitor is directly integrated on top of a MOSFET chip. The capacitor comprises multi layers of conductive material and dielectric material staking on top of each other with connection vias through dielectric layer for connecting different conductive layers. The method of integrating the bypass capacitor comprises repeating steps of depositing a dielectric layer, forming connection vias through the dielectric layer, depositing a conductive layer and patterning the conductive layer.

Abstract: An upper electrode of a capacitor has a two-layer structure of first and second upper electrodes. A gate electrode of a MOS field effect transistor and a fuse are formed by patterning conductive layers used to form the lower electrode, first upper electrode and second upper electrode of the capacitor. In forming a capacitor and a fuse on a semiconductor substrate by a conventional method, at least three etching masks are selectively used to pattern respective layers to form the capacitor and fuse before wiring connection. The number of etching masks can be reduced in manufacturing a semiconductor device having capacitors, fuses and MOS field effect transistors so that the number of processes can be reduced and it becomes easy to improve the productivity and reduce the manufacture cost.

Abstract: A semiconductor device including a substrate, an epitaxial layer, a first sinker, a transistor, a diode unit, a first buried layer, and a second buried layer is provided. When the semiconductor device is operated at the high voltage, the highly large substrate current due to the external load is avoided through the diode unit disposed in the semiconductor device of an embodiment consistent with the invention. Furthermore, according to the design of the semiconductor device, the issue of the narrow input voltage range is improved, and interference of the semiconductor device with the other semiconductor devices is prevented.

Abstract: A semiconductor device includes a resistive element and a MISFET. The resistive element includes a first conductive film formed on the semiconductor substrate and containing a metal, a second conductive film formed on the first conductive film and containing silicon, and an insulating film formed between the first conductive film and the second conductive film.

Abstract: The present disclosure provides an integrated circuit. The integrated circuit includes a semiconductor substrate; and a passive polysilicon device disposed over the semiconductor substrate. The passive polysilicon device further includes a polysilicon feature; and a plurality of electrodes embedded in the polysilicon feature.

Abstract: A semiconductor device comprises a capacitor in which a lower electrode, an adhesive layer, a capacitance insulating film, and an upper electrode are provided in series. The capacitance insulating film has laminated films in which a first metal oxide film and a second metal oxide film are alternatively laminated so that the first metal oxide film contacts with the adhesive layer. The adhesive layer has thickness of 0.3 nm or more and is an oxide film including at least one element selected from element contained in the lower electrode.

Abstract: A method for forming a structure on a surface of a semiconductor. The method includes: forming the material as a lower layer of the structure using a first deposition process to provide the lower layer with a first etch rate to a predetermined etchant; forming the upper layer of the structure with the material on the lower using a second deposition process to provide the upper layer with a second etch rate to the predetermined etchant higher than the first etch rate; and applying the predetermined etchant to upper layer to selectively remove the upper while leaving the lower layer.

Abstract: A semiconductor device includes: a semiconductor substrate; a lateral MOS transistor disposed in the substrate; a Zener diode disposed in the substrate; and a capacitor disposed in the substrate. The transistor includes a drain and a gate, and the diode and the capacitor are coupled in series between the drain and the gate. This device has minimized dimensions and high switching speed. Further, both of a switching loss and a surge voltage are improved.