Abstract: A monolithic metal oxide semiconductor field effect transistor (MOSFET)-Schottky diode device including a chip, a MOSFET, a Schottky diode and a termination structure is provided. The chip is divided into a transistor region, a diode region and a termination region. The MOSFET is disposed on the transistor region. The Schottky diode is disposed on the diode region. The termination structure is disposed on the termination region. The transistor region and the diode region are divided by the termination region. The MOSFET and Schottky diode share the termination structure.

Abstract: An integrated circuit structure includes a substrate, a semiconductor device supported by the substrate, and a guard ring structure disposed around the semiconductor device, the guard ring structure forming a Schottky junction. In an embodiment, the Schottky junction is formed from a p-type metal contact and an n-type guard ring. In an embodiment, the guard ring structure is electrically coupled to a positive or negative supply voltage.

Abstract: A device includes a semiconductor substrate, first and second electrodes supported by the semiconductor substrate, laterally spaced from one another, and disposed at a surface of the semiconductor substrate to form an Ohmic contact and a Schottky junction, respectively. The device further includes a conduction path region in the semiconductor substrate, having a first conductivity type, and disposed along a conduction path between the first and second electrodes, a buried region in the semiconductor substrate having a second conductivity type and disposed below the conduction path region, and a device isolating region electrically coupled to the buried region, having the second conductivity type, and defining a lateral boundary of the device. The device isolating region is electrically coupled to the second electrode such that a voltage at the second electrode during operation is applied to the buried region to deplete the conduction path region.

Abstract: An integrated circuit includes a plurality of trench MOSFET and a plurality of trench Schottky rectifier. The integrated circuit further comprises: tilt-angle implanted body dopant regions surrounding a lower portion of all trenched gates sidewalls for reducing Qgd; a source dopant region disposed below trench bottoms of all trenched gates for functioning as a current path for preventing a resistance increased caused by the tilt-angle implanted body dopant regions.

Abstract: A combined semiconductor rectifying device includes PN-junction silicon diode and Schottky barrier diode exhibiting a breakdown voltage higher than the breakdown voltage of PN-junction silicon diode, and Schottky barrier diode is made of a semiconductor, the band gap thereof is wider than the band gap of silicon. The combined semiconductor rectifying device exhibits a shortened reverse recovery time, low reverse leakage current characteristics and a high breakdown voltage, and is used advantageously in an electric power converter.

Abstract: A transistor includes a substrate including a trench, an insulation layer filled in a portion of the trench, the insulation layer having a greater thickness over an edge portion of a bottom surface of the trench than over a middle portion of the bottom surface of the trench, a gate insulation layer formed over inner sidewalls of the trench, the gate insulation layer having a thickness smaller than the insulation layer, and a gate electrode filled in the trench.

Abstract: A Schottky diode includes a device structure having a central portion and a plurality of fingers. Distal portions of the fingers overlie leakage current control (LCC) regions. An LCC region is relatively narrow and deep, terminating in proximity to a buried layer of like polarity. Under reverse bias, depletion regions forming in an active region lying between the buried layer and the LCC regions occupy the entire extent of the active region and thereby provide a carrier depleted wall. An analogous depletion region occurs in the active region residing between any pair of adjacent fingers. If the fingers include latitudinal oriented fingers and longitudinal oriented fingers, depletion region blockades in three different orthogonal orientations may occur. The formation of the LCC regions may include the use of a high dose, low energy phosphorous implant using an LCC implant mask and the isolation structures as an additional hard mask.

Abstract: Embodiments of semiconductor devices and driver circuits include a semiconductor substrate having a first conductivity type, an isolation structure (including a sinker region and a buried layer), an active device within area of the substrate contained by the isolation structure, and a diode circuit. The buried layer is positioned below the top substrate surface, and has a second conductivity type. The sinker region extends between the top substrate surface and the buried layer, and has the second conductivity type. The active device includes a source region of the first conductivity type, and the diode circuit is connected between the isolation structure and the source region. The diode circuit may include one or more Schottky diodes and/or PN junction diodes. In further embodiments, the diode circuit may include one or more resistive networks in series and/or parallel with the Schottky and/or PN diode(s).

Abstract: The present invention aims to enhance the reliability of a semiconductor device equipped with a Schottky barrier diode within the same chip, and its manufacturing technology. The semiconductor device includes an n-type n-well region formed over a p-type semiconductor substrate, an n-type cathode region formed in part thereof and higher in impurity concentration than the n-well region, a p-type guard ring region formed so as to surround the n-type cathode region, an anode conductor film formed so as to integrally cover the n-type cathode region and the p-type guard ring region and to be electrically coupled thereto, n-type cathode conduction regions formed outside the p-type guard ring region with each separation portion left therebetween, and a cathode conductor film formed so as to cover the n-type cathode conduction regions and to be electrically coupled thereto. The anode conductor film and the n-type cathode region are Schottky-coupled to each other.

Abstract: An embodiment is a semiconductor structure. The semiconductor structure comprises a p-type region in a substrate; a first n-type well in the p-type region; a first p-type well in the p-type region; and a second p-type well in the first p-type well. A concentration of a p-type impurity in the first p-type well is less than a concentration of a p-type impurity in the second p-type well. Additional embodiments further comprise further n-type and p-type wells in the substrate. A method for forming a semiconductor structure is also disclosed.

Abstract: A semiconductor layer has a second impurity concentration. First trenches are formed in the semiconductor layer to extend downward from an upper surface of the semiconductor layer. Each of insulation layers is formed along each of the inner walls of the first trenches. Each of conductive layers is formed to bury each of the first trenches via each of the insulation layers, and extends downward from the upper surface of the semiconductor layer to a first position. A first semiconductor diffusion layer reaches a second position from the upper surface of the semiconductor layer, is positioned between the first trenches, and has a third impurity concentration lower than the second impurity concentration. A length from the upper surface of the semiconductor layer to the second position is equal to or less than half a length from the upper surface of the semiconductor layer to the first position.

Abstract: To reduce size of a finished product by reducing the number of externally embedded parts, embedding of a Schottky barrier diode relatively large in the amount of current in a semiconductor integrated circuit device has been pursued. It is general practice to densely arrange a number of contact electrodes in a matrix over a Schottky junction region. A sputter etching process to the surface of a silicide layer at the bottom of each contact hole is performed before a barrier metal layer is deposited. However, in a structure in which electrodes are thus arranged over a Schottky junction region, a reverse leakage current in a Schottky barrier diode is varied by variations in the amount of sputter etching. The present invention is a semiconductor integrated circuit device having a Schottky barrier diode in which contact electrodes are arranged over a guard ring in contact with a peripheral isolation region.

Abstract: Disclosed are systems, devices and methods for providing electrostatic discharge (ESD) protection for integrated circuits. In some implementations, first and second conductors with ohmic contacts on an intrinsic semiconductor region can function similar to an x-i-y type diode, where each of x and y can be n-type or p-type. Such a diode can be configured to turn on under selected conditions such as an ESD event. Such a structure can be configured so as to provide an effective ESD protection while providing little or substantially nil effect on radio-frequency (RF) operating properties of a device.

Abstract: A semiconductor device for use in a power supply circuit has first and second MOSFETS. The source-drain path of one of the MOSFETS are coupled to the source-drain path of the other, and a load element is coupled to a connection node of the source-drain paths. The second MOSFET is formed on a semiconductor substrate with a Schottky barrier diode. First gate electrodes of the second MOSFET are formed in trenches in a first region of the semiconductor substrate, while second gate electrodes of the second MOSFET are formed in trenches in a second region of the semiconductor substrate. The first and second gate electrodes are electrically connected together. Portions of the Schottky barrier diode are formed between adjacent ones of the second gate electrodes. A center-to-center spacing between adjacent first gate electrodes is smaller than a center-to-center spacing between adjacent second gate electrodes.

Abstract: A high TCR tungsten resistor on a reverse biased Schottky diode. A high TCR tungsten resistor on an unsilicided polysilicon platform geometry. A high TCR tungsten resistor between two parallel polysilicon leads on remaining contact etch stop dielectric. A high TCR tungsten resistor embedded in a intermetal dielectric layer above a lower interconnect layer and below an upper interconnect layer. A method of forming a high TCR tungsten resistor on a reverse biased Schottky diode. A method of forming high TCR tungsten resistor on an unsilicided polysilicon platform geometry. A method of forming high TCR tungsten resistor between two parallel polysilicon leads on remaining contact etch stop dielectric. A method of forming high TCR tungsten resistor embedded in a inter metal dielectric layer above a lower interconnect layer and below an upper interconnect layer.

Abstract: A semiconductor system having a trench MOS barrier Schottky diode, having an integrated substrate PN diode as a clamping element (TMBS-ub-PN), suitable in particular as a Zener diode having a breakdown voltage of approximately 20V for use in a vehicle generator system, the TMBS-sub-PN being made up of a combination of Schottky diode, MOS structure, and substrate PN diode, and the breakdown voltage of substrate PN diode BV_pn being lower than the breakdown voltage of Schottky diode BV_schottky and the breakdown voltage of MOS structure BV_mos.

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 trench MOS barrier Schottky diode having an integrated PN diode and a method is for manufacturing same.

Abstract: A semiconductor device formed on a substrate includes a first diode junction formation, a second diode junction formation, and at least one through-silicon-via (TSV), in which a cathode and an anode of the first diode are cross-connected to an anode and cathode of the second diode through the at least one TSV for achieving electrical robustness in through-silicon-via based integrated circuits, including photosensitive devices and circuits for signal processing applications.

Abstract: The present invention provides a semiconductor device including: a base substrate; a first semiconductor layer which is disposed on the base substrate and has a front surface and a rear surface opposite to the front surface; first ohmic electrodes disposed on the front surface of the first semiconductor layer; a second ohmic electrode disposed on the rear surface of the first semiconductor layer; a second semiconductor layer interposed between the first semiconductor layer and the first ohmic electrodes; and a Schottky electrode part which covers the first ohmic electrodes on the front surface of the first semiconductor layer.

Abstract: A semiconductor structure is provided. A second area is disposed between first and third areas. An epitaxial layer is on a substrate. A body layer is in the epitaxial layer in first and second areas. First and second gates are in the body layer and in a portion of the epitaxial layer. The first gate is in the substrate and partially in first and second areas. The second gate is in the substrate and partially in second and third areas. A first contact plug is in a portion of the body layer in the first area. A second contact plug is at least in the epitaxial layer in the third area and contacts the epitaxial layer and the second gate. The first contact plug is electrically connected to the second contact plug. A first doped region is in the body layer between the first contact plug and the first gate.

Abstract: A Schottky diode includes a semiconductor layer formed on a semiconductor substrate; first and second trenches formed in the semiconductor layer where the first and second trenches are lined with a thin dielectric layer and being filled partially with a trench conductor layer and remaining portions of the first and second trenches are filled with a first dielectric layer; and a Schottky metal layer formed on a top surface of the semiconductor layer between the first trench and the second trench. The Schottky diode is formed with the Schottky metal layer as the anode and the semiconductor layer between the first and second trenches as the cathode. The trench conductor layer in each of the first and second trenches is electrically connected to the anode of the Schottky diode. In one embodiment, the Schottky diode is formed integrated with a trench field effect transistor on the same semiconductor substrate.

Abstract: Provided is a semiconductor device having an anode of a Si-FRD and a cathode of a Si-SBD which are serially connected. The Si-SBD has a junction capacitance whose amount of accumulable charge is equal to or more than an amount of charge occurring at the time of reverse recovery of the Si-FRD, and has a lower breakdown voltage than the Si-FRD does.

Abstract: Disclosed is a semiconductor device including: a base substrate; a semiconductor layer disposed on the base substrate; an ohmic electrode part which has ohmic electrode lines disposed in a first direction, on the semiconductor layer; and a Schottky electrode part which is disposed to be spaced apart from the ohmic electrode lines on the semiconductor layer and includes Schottky electrode lines disposed in the first direction, wherein the Schottky electrode lines and the ohmic electrode lines are alternately disposed in parallel, and the ohmic electrode part further includes first ohmic electrodes covered by the Schottky electrode lines on the semiconductor layer.

Abstract: A semiconductor junction barrier Schottky (JBS-SKY) diode with enforced upper contact structure (EUCS) is disclosed. Referencing an X-Y-Z coordinate, the JBS-SKY diode has semiconductor substrate (SCST) parallel to X-Y plane. Active device zone (ACDZ) atop SCST and having a JBS-SKY diode with Z-direction current flow. Peripheral guarding zone (PRGZ) atop SCST and surrounding the ACDZ. The ACDZ has active lower semiconductor structure (ALSS) and enforced active upper contact structure (EUCS) atop ALSS. The EUC has top contact metal (TPCM) extending downwards and in electrical conduction with bottom of EUCS; and embedded bottom supporting structure (EBSS) inside TPCM and made of a hard material, the EBSS extending downwards till bottom of the EUCS. Upon encountering bonding force onto TPCM during packaging of the JBS-SKY diode, the EBSS enforces the EUCS against an otherwise potential micro cracking of the TPCM degrading the leakage current of the JBS-SKY diode.

Abstract: The present disclosure relates to a nitride electronic device and a method for manufacturing the same, and particularly, to a nitride electronic device and a method for manufacturing the same that can implement various types of nitride integrated structures on the same substrate through a regrowth technology (epitaxially lateral over-growth: ELOG) of a semi-insulating gallium nitride (GaN) layer used in a III-nitride semiconductor electronic device including Group III elements such as gallium (Ga), aluminum (Al) and indium (In) and nitrogen.

Abstract: A Schottky diode structure includes a semiconductor substrate having an anode region and a cathode region. A lightly doped region with a predetermined conductivity type is in the semiconductor substrate. A metal contact overlies the lightly doped region and corresponds to the cathode region to serve as a cathode. A metal silicide layer is beneath and electrically connected to the metal contact, wherein the metal silicide layer, directly under the metal contact, is in direct contact with the lightly doped region. A heavily doped region with the predetermined conductivity type is in the lightly doped region and corresponds to the anode region to serve as an anode.

Abstract: A semiconductor structure and a manufacturing method for the same are provided. The semiconductor structure includes a well region, a dielectric structure, a first doped layer, a second doped layer and a first doped region. The dielectric structure is on the well region. The dielectric structure has a first dielectric sidewall and a second dielectric sidewall opposite to each other. The dielectric structure includes a first dielectric portion and a second dielectric portion, between the first dielectric sidewall and the second dielectric sidewall. The first doped layer is on the well region between the first dielectric portion and the second dielectric portion. The second doped layer is on the first doped layer. The first doped region is in the well region on the first dielectric sidewall.

Abstract: To reduce size of a finished product by reducing the number of externally embedded parts, embedding of a Schottky barrier diode relatively large in the amount of current in a semiconductor integrated circuit device has been pursued. It is general practice to densely arrange a number of contact electrodes in a matrix over a Schottky junction region. A sputter etching process to the surface of a silicide layer at the bottom of each contact hole is performed before a barrier metal layer is deposited. However, in a structure in which electrodes are thus arranged over a Schottky junction region, a reverse leakage current in a Schottky barrier diode is varied by variations in the amount of sputter etching. The present invention is a semiconductor integrated circuit device having a Schottky barrier diode in which contact electrodes are arranged over a guard ring in contact with a peripheral isolation region.

Abstract: An integrated circuit device and method for fabricating the integrated circuit device is disclosed. The integrated circuit device includes a substrate, a diffusion source, and a lightly doped diffusion region in contact with a conductive layer. A junction of the lightly doped diffusion region with the conductive layer forms a Schottky region. An annealing process is performed to form the lightly doped diffusion region. The annealing process causes dopants from the diffusion source (for example, an n-well disposed in the substrate) of the integrated circuit device to diffuse into a region of the substrate, thereby forming the lightly doped diffusion region.

Abstract: An integrated circuit structure includes a semiconductor substrate; a first well region of a first conductivity type over the semiconductor substrate; a second well region of a second conductivity type opposite the first conductivity type encircling the first well region; and a metal-containing layer over and adjoining the first well region and extending over at least an inner portion of the second well region. The metal-containing layer and the first well region form a Schottky barrier. The integrated circuit structure further includes an isolation region encircling the metal-containing layer; and a third well region of the second conductivity type encircling at least a central portion of the first well region. The third well region has a higher impurity concentration than the second well region, and includes a top surface adjoining the metal-containing layer, and a bottom surface higher than bottom surfaces of the first and the second well regions.

Abstract: A silicon carbide semiconductor device with a Schottky barrier diode includes a first conductivity type silicon carbide substrate, a first conductivity type silicon carbide drift layer on a first surface of the substrate, a Schottky electrode forming a Schottky contact with the drift layer, and an ohmic electrode on a second surface of the substrate. The Schottky electrode includes an oxide layer in direct contact with the drift layer. The oxide layer is made of an oxide of molybdenum, titanium, nickel, or an alloy of at least two of these elements.

Abstract: A protective element for electronics has at least one Schottky diode and at least one Zener diode which are located between a power supply and the electronics, the anode of the Schottky diode being connected to the power supply and the cathode of the Schottky diode being connected to the electronics, and the cathode and the anode of the Zener diode are connected to ground. The Schottky diode is a trench MOS barrier junction diode or trench MOS barrier Schottky (TMBS) diode or a trench junction barrier Schottky (TJBS) diode and includes an integrated semiconductor arrangement, which has at least one trench MOS barrier Schottky diode and a p-doped substrate, which is used as the anode of the Zener diode.

Abstract: A method of producing a Schottky diode includes the steps of: forming a resist layer on the semiconductor substrate; performing a first exposure process on the resist layer; performing a first developing process for developing the resist layer to form a first Schottky diode having an excess region; performing a first cleaning process; performing a second exposure process on the first Schottky diode; performing a second developing process on the first Schottky diode to remove the excess region from the first Schottky diode so that a second Schottky diode corresponding to the specific Schottky diode is formed; and performing a second cleaning process.

Abstract: A Schottky diode comprises an ohmic layer that can serve as a cathode and a metal layer that can serve as an anode, and a drift channel formed of semiconductor material that extends between the ohmic and metal layers. The drift channel includes a heavily doped region adjacent to the ohmic contact layer. The drift channel forms a Schottky barrier with the metal layer. A pinch-off mechanism is provided for pinching off the drift channel while the Schottky diode is reverse-biased. As a result, the level of saturation or leakage current between the metal layer and the ohmic contact layer under a reverse bias condition of the Schottky diode is reduced.

Abstract: A gallium nitride based semiconductor diode includes a substrate, a semiconductor body including a first heavily doped GaN layer and a second lightly doped GaN layer. The semiconductor body includes mesas projecting upwardly from a lower surface where each of the mesas includes the second GaN layer and a portion of the first GaN layer. Schottky contacts are formed on the upper surface of the mesas and ohmic contacts are formed on the lower surface of the semiconductor body. An insulating layer is formed over the Schottky and ohmic contacts. Vias are formed in the insulating layer to the Schottky contacts and vias are formed in the semiconductor body to the Ohmic contacts. An anode electrode is formed in a first metal pad in electrical contact with the Schottky contacts. A cathode electrode is formed in a second metal pad in electrical contact with the ohmic contacts.

Abstract: A PFC module includes: a diode bridge having first and second diodes in the upper arm, and third and fourth diodes in the lower arm; and first and second switching elements for power factor correction. The first and second diodes are Schottky barrier diodes formed by using a wide bandgap semiconductor. The third and fourth diodes, and the first and second switching elements are Schottky barrier diodes and switching elements respectively formed by using silicon.

Abstract: To provide a Schottky electrode in a diamond semiconductor, which has a good adhesion properties to diamonds, has a contacting surface which does not become peeled due to an irregularity in an external mechanical pressure, does not cause a reduction in yield in a diode forming process and does not cause deterioration in current-voltage characteristics, and a method of manufacturing the Schottky electrode. A Schottky electrode which includes: scattered island-form pattern Pt-group alloy thin films which are formed on a diamond surface formed on a substrate, in which the Pt-group alloy includes 50 to 99.9 mass % of Pt and 0.

Abstract: A semiconductor chip includes: a semiconductor substrate; an interface member formed through the semiconductor substrate and electrically coupled to an external signal transfer terminal; and a backward diode formed between the semiconductor substrate and the interface member.

Abstract: A semiconductor device has a trench junction barrier Schottky diode that includes an integrated substrate p-n diode (TJBS-Sub-PN) as a clamping element, the trench junction barrier Schottky diode being suited, e.g., as a Zener diode having a breakdown voltage of approximately 20 V, for use in motor-vehicle generator systems. In this context, the TJBS-Sub-PN is made up of a combination of a Schottky diode, an epitaxial p-n diode and a substrate p-n diode, and the breakdown voltage of the substrate p-n diode (BV_pn) is less than the breakdown voltage of the Schottky diode (BV_schottky) and the breakdown voltage of the epitaxial p-n diode (BV_epi).

Abstract: Disclosed are semiconductor devices with breakdown voltages that are more controlled and stable after repeated exposure to breakdown conditions than prior art devices. The disclosed devices can be used to provide secondary circuit functions not previously contemplated by the prior art.

Abstract: To achieve a further reduction in the size of a finished product by reducing the number of externally embedded parts, the embedding of a Schottky barrier diode which is relatively large in the amount of current in a semiconductor integrated circuit device has been pursued. In such a case, it is general practice to densely arrange a large number of contact electrodes in a matrix over a Schottky junction region. It has been widely performed to perform a sputter etching process with respect to the surface of a silicide layer at the bottom of each contact hole before a barrier metal layer is deposited. However, in a structure in which electrodes are thus arranged over a Schottky junction region, a reverse leakage current in a Schottky barrier diode is varied by variations in the amount of sputter etching. The present invention is a semiconductor integrated circuit device having a Schottky barrier diode in which contact electrodes are arranged over a guard ring in contact with a peripheral isolation region.

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: A semiconductor device and a method for forming a semiconductor device are provided. The semiconductor device includes a semiconductor body with a first semiconductor region and a second semiconductor region spaced apart from each other. A first metallization is in contact with the first semiconductor region. A second metallization is in contact with the second semiconductor region. An insulating region extends between the first semiconductor region and the second semiconductor region. A semi-insulating region having a resistivity of about 103 Ohm cm to about 1014 Ohm cm is arranged on the insulating region and forms a resistor between the first metallization and the second metallization.

Abstract: The present invention aims to enhance the reliability of a semiconductor device equipped with a Schottky barrier diode within the same chip, and its manufacturing technology. The semiconductor device includes an n-type n-well region formed over a p-type semiconductor substrate, an n-type cathode region formed in part thereof and higher in impurity concentration than the n-well region, a p-type guard ring region formed so as to surround the n-type cathode region, an anode conductor film formed so as to integrally cover the n-type cathode region and the p-type guard ring region and to be electrically coupled thereto, n-type cathode conduction regions formed outside the p-type guard ring region with each separation portion left therebetween, and a cathode conductor film formed so as to cover the n-type cathode conduction regions and to be electrically coupled thereto. The anode conductor film and the n-type cathode region are Schottky-coupled to each other.

Abstract: A low profile high power Schottky barrier bypass diode for solar cells and panels with the cathode and anode electrodes on the same side of the diode and a method of fabrication thereof are disclosed for generating a thin chip with both electrodes being on the same side of the chip. In an embodiment, a mesa isolation with a Zener diode over the annular region surrounding the central region of the mesa anode in the Epi of the substrate is formed. In an embodiment, a P-type Boron dopant layer is ion implanted in the annular region for the Zener Diode. This controls recovery from high voltage spikes from the diode rated voltage. A Schottky barrier contact for the anode and a contact for the cathode are simultaneously created on the same side of the chip.

Abstract: A semiconductor arrangement is disclosed. One embodiment includes a first semiconductor layer including a first and second component zone that form a pn-junction or a Schottky-junction. A second semiconductor layer includes a drift control zone adjacent to the second component zone. A dielectric layer separates the first semiconductor layer from the second semiconductor layer. A rectifying element is coupled between the drift control zone and the second component zone.

Abstract: Semiconductor device having an on-chip type electrostatic discharge (ESD) protection circuit and a method of manufacturing the same are provided. The on-chip type ESD protection circuit may include a first junction diode having a first conductive type region contacting a second conductive type region in a semiconductor substrate, and a first schottky diode having a metallic material layer arranged on and contacting the first conductive type region of the semiconductor substrate.

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: Improved Schottky diodes with reduced leakage current and improved breakdown voltage are provided by building a JFET with its current path of a first conductivity type serially located between a first terminal comprising a Schottky contact and a second terminal. The current path lies (i) between multiple substantially parallel finger regions of a second, opposite, conductivity type substantially laterally outboard of the Schottky contact, and (ii) partly above a buried region of the second conductivity type that underlies a portion of the current path, which regions are electrically coupled to the first terminal and the Schottky contact and which portion is electrically coupled to the second terminal. When reverse bias is applied to the first terminal and Schottky contact, the current path is substantially pinched off in vertical or horizontal directions or both, thereby reducing the leakage current and improving the breakdown voltage of the device.