Abstract: An improved method for forming a fuse element is disclosed. During the formation of the upper capacitor plate in a capacitor structure, metals or their alloys are simultaneously patterned as an upper capacitor plate and as a fuse.

Abstract: A method of forming a metal fuse in a semiconductor device. In one embodiment, a specific additional mask is applied to form the metal fuse to reduce the thickness of the fuse. The method also includes forming a fuse window opening that is very shallow in the semiconductor device. The shallower opening allows for better control and removal of the remaining passivation left over the fuse during a fuse burning laser process. The thinner fuse and the thinner remaining passivation reduce the amount of laser energy required to vaporize the oxide and to cut the fuse. The location of the fuse also greatly enlarges the laser energy window that can be utilized to make laser repairs. The larger energy window results in a higher laser repair success ratio even if some deviation in the fabrication process occurs.

Abstract: A method of forming a fuse structure in which passivating material over the fuse has a controlled, substantially uniform thickness that is provided after C4 metallurgy formation. A laser fuse deletion process for the fuse formed by this method is also disclosed.

Abstract: An integrated circuit for providing electrostatic discharge protection that includes a contact pad, a CMOS device including a transistor having a substrate, and a CDM clamp for providing electrostatic discharge protection coupled between the contact pad and the CMOS device, the CDM clamp including at least one active device, wherein the CDM clamp conducts electrostatic charges accumulated in the substrate of the transistor to the contact pad and wherein the CMOS device is coupled between a high voltage line and a low voltage line.

Abstract: The present invention provides a system and method for processing low voltage threshold transistors on a semiconductor wafer. The method may include: forming core transistors with drains on the semiconductor wafer; forming low voltage threshold transistors with drains on the semiconductor wafer; forming input output transistors with drains on the semiconductor wafer; forming a spacing layer over the core, low voltage and input output transistors; forming a first photoresist mask layer over the low voltage transistors; doping the drains of the core and the input output transistors, wherein the doping is a medium doping; forming a second photoresist mask layer over the input output transistors; and doping the drains of the core and the low voltage threshold transistors, wherein the doping is a medium doping.

Abstract: Fuses for integrated circuits and semiconductor devices and methods for using the same. The semiconductor fuse contains two conductive layers—an overlying and underlying refractory metal nitride layer—on an insulating substrate. The semiconductor fuse may be fabricated during manufacture of a local interconnect structure including the same materials. The fuse, which may be used to program redundant circuitry, may be blown by electrical current rather than laser beams, thus allowing the fuse width to be smaller than prior art fuses blown by laser beams. The fuse may also be blown by less electrical current than the current required to blow conventional polysilicon fuses having similar dimensions.

Abstract: A semiconductor structure that includes at least one circuit element of a fuse, a diffusion barrier or a capacitor that is formed by refractory metal-silicon-nitrogen is disclosed. A method for fabricating such semiconductor structure that includes a fuse element, a diffusion barrier, a resistor or a capacitor by a refractory metal-silicon-nitrogen material is further disclosed. A suitable refractory metal-silicon-nitrogen material to be used is TaSiN which provides a wide range of resistivity by changing the ratio of Ta:Si:N. The invention provides the benefit that the various components of diffusion barriers, fuses, capacitors and resistors may be formed by a single deposition process of a TaSiN layer, the various components are then selectively masked and treated by either heat-treating or ion-implantation to vary their resistivity selectively while keeping the other shielded elements at the same resistivity.

Abstract: A data signal voltage on a signal line 102 is held in a voltage holding capacitor 106 through an n-type MOS transistor 103 switched on by a gate scan voltage, and supplied to an analog amplifier circuit 104-1. The analog amplifier circuit 104-1 is formed of an MOS transistor having a double gate structure, and the operating point thereof is set at an operating range in which dependence of Ids on Vds is substantially nullified. Even when Vds is varied due to a response of liquid crystal 109, Ids is substantially fixed. Accordingly, the pixel voltage which is substantially proportional to the data signal voltage can be applied to the liquid crystal 109.

Abstract: A configuration of fuses in a semiconductor structure having Cu metallization planes is provided. The semiconductor structure has an Al metal layer on the topmost interconnect plane for providing Al bonding pads. The fuses are configured as Al fuses and, in the semiconductor structure having Cu metallization planes, are provided above the diffusion barrier of the topmost Cu metallization plane but below a passivation layer.

Abstract: A novel fuse structure. An optimal position of laser spot is defined above a substrate. A first conductive layer is formed on part of the substrate. A dielectric layer is formed on the substrate and the first conductive layer. A second conductive layer comprising the position of laser spot is formed on part of the dielectric layer. A third conductive layer is formed on the part of the dielectric layer placed above the first conductive layer, wherein the third conductive layer is insulated from the first and second conductive layers. At least one conductive plug penetrates the dielectric layer, to electrically connect the first conductive layer and the second conductive layer. Thus, the third conductive layer serves as a floating layer to prevent the first conductive layer from being damaged in the laser blow process.

Abstract: A magnetic memory cell is disclosed. The memory cell includes first conductor and second conductors coupled to first and second electrodes of a magnetic element. A plurality of memory cells is interconnected by first and second conductors to form a memory array or block. The second conductor is coupled to the second electrode via a conductive strap having a fuse portion. The fuse portion can be blown to sever the connection between the second conductor and magnetic element, Nitride.

Abstract: A complementary metal oxide semiconductor (CMOS) fabrication process. The process comprises creating a polysilicon layer having a first thickness for a transistor gate area and a second thickness for a fuse area. The first thickness is greater than the second thickness, wherein most of the polysilicon in the fuse area will react with a metal layer to form polysilicide during a rapid thermal anneal (RTA) process.

Abstract: A copper fuse structure and the method for fabricating the same is disclosed in this present invention. By employing an inner copper metal layer as a fuse, the copper fuse according to this invention can be easily zipped with a laser repair tool. Furthermore, the openings on a bonding pad and the fuse of the semiconductor structure can be identified with the method according to this invention. Moreover, in contrast of the fuse formed with an upper aluminum layer in the prior art, the cost of the fuse manufacturing is lower in the method according to this invention by fabricating the fuse with an inner copper layer.

Abstract: A structure and method of fabricating a semiconductor corrosion resistant metal fuse line including a refractory liner which can also act as a resistor is disclosed. Fabrication is accomplished using damascene process. The metal structure can be formed on a semiconductor substrate including a first portion including a first layer and a second layer, the first layer having higher resistivity than the second layer, the second layer having horizontal and vertical surfaces that are in contact with the first layer in the first portion, and a second portion coupled to the first portion, the second portion being comprised of the first layer, the first layer not being in contact with the horizontal and vertical surfaces of the second layer in the second portion. The metal structure can be used as a corrosion resistant fuse. The metal structure can also be used as a resistive element. The high voltage tolerant resistor structure allows for usage in mixed-voltage, and mixed signal and analog/digital applications.

Abstract: A method of fabrication used for semiconductor integrated circuit devices to define a thin copper fuse at a top via opening, in a partial etch, dual damascene integration scheme, efficiently reducing top metal thickness in a fusible link, for the purpose of laser ablation. Some advantages of the method are: (a) avoids copper fuse contact to low dielectric material, which is subject to the thermal shock of laser ablation, (b) increases insulating material thickness over the fuse using better thickness control, and most importantly, (c) reduces the copper fuse thickness, for easy laser ablation of the copper fuse, and finally, (d) uses USG, undoped silicate glass to avoid direct contact with low dielectric constant materials.

Abstract: A method of forming a fuse structure in which passivating material over the fuse has a controlled, substantially uniform thickness that is provided after C4 metallurgy formation. A laser fuse deletion process for the fuse formed by this method is also disclosed.

Abstract: A method and structure for a fuse structure comprises an insulator layer, a plurality of fuse electrodes extending through the insulator layer to an underlying wiring layer, an electroplated fuse element connected to the electrodes, and an interface wall. The fuse element is positioned external to the insulator, with a gap juxtaposed between the insulator and the fuse element. The interface wall further comprises a first side wall, a second side wall, and an inner wall, wherein the inner wall is disposed within the gap. The fuse electrodes are diametrically opposed to one another, and the fuse element is perpendicularly disposed above the fuse electrodes. The fuse element is either electroplatted, electroless plated, or is an ultra thin fuse.

Abstract: Disclosed is a method of ball grid array packaging, comprising the steps of providing a semiconductor die having a metal conductors thereon, covering said metal conductors with an insulative layer, etching through said insulative layer so as to provide one or more openings to said metal conductors, depositing a compliant material layer, etching through said compliant material layer so as to provide one or more openings to said metal conductors, depositing a substantially homogenous conductive layer, patterning said conductive layer so as to bring at least one of said metal conductors in electrical contact with one or more pads, each said pad comprising a portion of said conductive layer disposed upon said compliant material, and providing solder balls disposed upon said pads. Also disclosed is the apparatus made from the method.

Abstract: The present invention relates to a method of forming a metal feature on an intermediate structure of a semiconductor device that comprises a first exposed metal structure and a second exposed metal structure. The metal feature is selectively formed on the first exposed metal structure without forming on the second exposed metal structure. By adjusting a concentration of stabilizer in an electroless plating solution, the metal feature is electrolessly plated on the first exposed metal structure without plating metal on the second exposed metal structure.

Abstract: Fuses for integrated circuits and semiconductor devices, methods for making the same, methods of using the same, and semiconductor devices containing the same. The semiconductor fuse contains two conductive layers—an overlying and underlying layer—on an insulating substrate. The underlying layer comprises titanium nitride and the overlying layer comprises tungsten silicide. The semiconductor fuse may be fabricated during manufacture of a local interconnect structure containing the same materials. The fuse, which may be used to program redundant circuitry, is blown by electrical current rather than laser beams, thus allowing the fuse width to be smaller than prior art fuses blown by laser beams. The fuse may also be blown by less electrical current than the current required to blow conventional polysilicon fuses having similar dimensions.

Abstract: A nonvolatile read-only memory device, wherein a word line is on a substrate and the word line includes a metal layer a polysilicon line. A trapping layer is further located between the word line and the substrate. A polysilicon protection line is formed over the substrate and the polysilicon protection line connects the word line and a grounded doped region in the substrate, wherein the resistance of the polysilicon protection line is higher than that of the word line.

Abstract: An embodiment of the instant invention is a method of implementing a vanishingly small integrated circuit diode comprising the steps of: forming an area of a thin dielectric film (201 of FIG. 2) over a conductive silicon surface ( 10 of FIG. 2) of one conductivity type in a region of a thick dielectric film (100 of FIG. 2) over the conductive silicon surface; forming a first conductive path from the conductive silicon surface to an operating circuit; forming a conductive silicon film (202 of FIG. 2) of a second conductivity type over the thin dielectric region; forming a second conductive path from the conductive silicon film to the operating circuit; and causing at least one region of the second conductivity type in the conductive silicon surface and at least one third conductive path through the thin dielectric film wherein said causing consists of applying a voltage or applying a current.

Abstract: Disclosed is a conductive fuse for a semiconductor device, comprising: a pair of contact portions integrally connected to a fusible portion by connecting portions; the contact portions thicker than the connecting portions and the connecting portions thicker than the fusible portion; a first dielectric under the connecting portions and the fusible portion and extending between the pair of contact portions; and a second dielectric between the first dielectric and the fusible portion, the second dielectric extending between the connecting portions and defining the length of the fusible portion.

Abstract: A semiconductor device has a fuse to be blown with an energy beam. The semiconductor device has copper wiring levels formed on a semiconductor substrate on which semiconductor elements are formed, an uppermost wiring level formed on said copper wiring levels and including a refractory metal film connected to a top one of the copper wiring levels, the fuse formed from a part of the uppermost wiring level, and a surface protective film formed on the uppermost wiring level.

Abstract: An integrated circuit includes a first conductive layer, an insulator layer disposed on the first conductive layer, and a second conductive layer disposed on the insulator layer. A first fuse is disposed in the first conductive layer and provides a first signal, and a second fuse is disposed in the second conductive layer in alignment with the first fuse and provides a second signal.

Abstract: A fabrication method for forming a semiconductor device having a fuse is provided. A substrate includes a cell array area, a peripheral circuit area and a global step difference between the cell array area and the peripheral circuit area. The substrate comprises a fuse formed in the peripheral circuit of the substrate. An interlayer insulating layer is formed on the global step difference. The global step difference is reduced by a cell open process. A multilevel metal interconnection including an intermetal insulating layer is formed on the resultant structure. During the cell open process and/or the process for forming the multilevel metal interconnection, the interlayer insulating layer and/or the intermetal insulating layer is partially removed to form a recess. A passivation layer is formed on the multilevel metal interconnection. A fuse opening is formed through the recess to expose the fuse.

Abstract: The present invention provides a system, apparatus and method of programming via electromigration. A semiconductor fuse which includes a cathode and an anode coupled by a fuse link having an electrically conductive component, such as silicide, is coupled to a power supply. A potential is applied across the conductive fuse link via the cathode and anode in which the potential is of a magnitude to initiate electromigration of silicide from a region of the semiconductor fuse reducing the conductivity of the fuse link. The electromigration is enhanced by effectuating a temperature gradient between the fuse link and one of the cathode and anode responsive to the applied potential. Portions of the semiconductor fuse are selectively cooled in a heat transfer relationship to increase the temperature gradient. In one embodiment, a heat sink is applied to the cathode. The heat sink can be a layer of metal coupled in close proximity to the cathode while insulated from the fuse link.

Abstract: In a semiconductor device having a fuse and an etching stopper film covering the fuse, an optical window exposing the etching stopper film and a contact hole exposing a conductor pattern are formed simultaneously. By applying a dry etching process further to the etching stopper film, an insulation film covering the fuse is exposed in the optical window.

Abstract: Provided is an organic thin film transistor comprising a siloxane polymeric layer interposed between a gate dielectric and an organic semiconductor layer. An integrated circuit comprising thin film transistors and methods of making a thin film transistor are also provided. The organic thin film transistors of the invention typically exhibit improvement in one or more transistor properties.

Abstract: The semiconductor device includes a semiconductor substrate, an insulating layer on the semiconductor substrate wherein a groove is patterned to a predetermined depth in an upper surface of the insulating layer, a fuse layer at sidewalls and on a bottom of the groove, and a wire connected electrically to the fuse layer.

Abstract: A method for providing a fill pattern for integrated circuit designs is disclosed. A keepout file having keepout data is generated from a chip design layout file having chip design layout data. The keepout file includes a map of areas of an integrated circuit design where fill patterns cannot be placed. The map of areas from the keepout file is then overlaid with a fill pattern to yield a fill-pattern file. Fill patterns from the fill-pattern file is removed from locations that coincide with locations as defined by the keepout data to yield a final-fill file with crucial fill pattern data. The crucial fill pattern data from the final-fill file is overlaid on the design layout data in the chip design layout file to yield a complete design layout file. Finally, the design rule integrity and logical to physical correspondence of the complete design layout file is verified.

Abstract: A fabrication method for forming a semiconductor device having a fuse is provided. A substrate includes a cell array area, a peripheral circuit area and a global step difference between the cell array area and the peripheral circuit area. The substrate comprises a fuse formed in the peripheral circuit of the substrate. An interlayer insulating layer is formed on the global step difference. The global step difference is reduced by a cell open process. A multilevel metal interconnection including an intermetal insulating layer is formed on the resultant structure. During the cell open process and/or the process for forming the multilevel metal interconnection, the interlayer insulating layer and/or the intermetal insulating layer is partially removed to form a recess. A passivation layer is formed on the multilevel metal interconnection. A fuse opening is formed through the recess to expose the fuse.

Abstract: A method of forming an integrated circuit device can include forming a plurality of fuse wires on an integrated circuit substrate, and forming an insulating layer on the integrated circuit substrate and on the plurality of fuse wires so that the fuse wires are between the integrated circuit substrate and the insulating layer. A plurality of fuse cutting holes can be formed in the insulating layer wherein each of the fuse cutting holes exposes a target spot on a respective one of the fuse wires, and a cross-sectional area of the fuse wires can be reduced at the exposed target spots. Related structures are also discussed.

Abstract: A severable horizontal portion of a fuse link is formed relative to a vertically configured structure in an IC to promote separation of the severable portion upon applying energy from a laser beam. The vertically configured structure may be a reduced vertical thickness of the severable portion, an elevated lower surface of the severable portion above adjoining portions of the fuse link, a protrusion which supports the severable portion at a height greater than a height of the adjoining portions of the fuse link, flowing the melted severable portion down sloped surfaces away from a break point, and a propellent material beneath the severable portion which explodes to ablate the severable portion.

Abstract: An integrated circuit has primary devices and redundant devices being selective substituted for the primary devices through at least one fuse. The fuse includes a first layer having at least one fuse link region, a second layer over the first layer and cavities in the second layer above the fuse link region.

Abstract: A semiconductor device having a fuse evaluation circuit is provided. Fuse evaluation circuit (100) can include, a reference voltage generation circuit (110), a fuse circuit (120-n), and a fuse evaluation control circuit (130). Fuse circuit (120-n) can include a fuse (Fn) and evaluation transistor (Tn) arranged in-series and providing an evaluation node (Nn) at their connection. Reference voltage generation circuit (110) can provide a reference voltage (VG1) at a control gate of evaluation transistor (Tn). Fuse evaluation control circuit (130) can vary the impedance of the evaluation transistor (Tn) by varying the potential of reference voltage (VG1). Fuse evaluation circuit (100) can evaluate the condition of fuse (Fn) accordingly.

Abstract: A semiconductor fuse is positioned between conductors for connecting wiring lines. The fuse comprises spacers positioned on adjacent ones of the conductors, and a fuse element positioned between the spacers and connected to the wiring lines. A space between the conductors comprises a first width comprising a smallest possible photolithographic width and the fuse element has a second width smaller than the first width.

Abstract: A process for forming a capacitive structure and a fuse structure in an integrated circuit device includes forming a first capacitor plate and first and second fuse electrodes in a first dielectric layer of the device. In a second dielectric layer overlying the first dielectric layer, a capacitor dielectric section overlying the first capacitor plate, and a fuse barrier section overlying and between the first and second fuse electrodes are formed simultaneously. In a conductive layer overlying the second dielectric layer, a second capacitor plate overlying the capacitor dielectric section, and a fuse overlying the fuse barrier section and contacting the first and second fuse electrodes are formed simultaneously. The capacitor dielectric section and the fuse barrier section may be defined simultaneously by selectively removing portions of the first dielectric layer during a single etching step.

Abstract: The present invention provides a method for reducing plasma damage to a gate oxide of a metal-oxide semiconductor (MOS) transistor positioned on a substrate of a MOS semiconductor wafer. The method begins with the formation of a dielectric layer covering the MOS transistor on the substrate. An etching process is then performed to form a first contact hole through the dielectric layer to a gate on the surface of the MOS transistor, as well as to form a second contact hole through the dielectric layer to an n-well in the substrate. A bypass circuit, positioned on the dielectric layer and the first and second contact holes, and a fusion area are then formed. The fusion area, electrically connecting with the bypass circuit, also electrically connects with the MOS transistor and the n-well thereafter. Ions produced during the process are thus transferred to the n-well via the conductive wire so as to reduce plasma damage to the gate oxide.

Abstract: A method for fabricating an array of ultra-small pores for use in chalcogenide memory cells. A layer of a first material is applied onto a substrate. A portion of the layer of the first material is then removed to define an upper surface with vertical surfaces extending therefrom to a lower surface in the first layer of the first material. A fixed layer of a second material is then applied onto the vertical surfaces of the first layer of the first material. The fixed layer of the second material has a first thickness. A second layer of the first material is then applied onto the fixed layer of the second material. The fixed layer of the second material is then removed to define an array of pores in the first material layers. The pores thus defined have minimum lateral dimensions ranging from approximately 50 to 500 Angstroms and cross sectional areas greater than or equal to the first thickness of the second layer squared.

Abstract: A semiconductor device with a fuse box includes at least two gate electrodes 8, 9 and a fuse member 6. The two gate electrodes 8, 9 are formed on at least one insulating film 13 on a semiconductor substrate 100. The fuse member 6 is formed on the insulating film 13 on the semiconductor substrate 100. The two gate electrodes 8, 9 are electrically connected each other by the fuse member 6. In addition, the insulating film 13 and a field region 2 constituted by a semiconductor region are arranged adjacent to each other in a frame-like guard ring 1. The guard ring 1 is constituted by a semiconductor region formed on the semiconductor substrate 100.

Abstract: A defect removable semiconductor element and the manufacturing method thereof are provided with a protective layer covering fuses exposed at a part of the redundancy memory cell region, the layer being thinner than the one covering the main memory cell region, so that a predetermined fuse is cut off for removing a defect without damaging adjacent fuses even if the amount of energy of laser beam to be applied is greater and the size of the spot to be focused is bigger, thereby improving operational conditions in the energy of the laser beam to be applied and the size of a spot to be focused and the operational reliability in removing a defect.

Abstract: A substrate having at least one fuse in a fuse layer. An upper etch-stop layer over the fuse, a lower etch-stop layer having a different etch-chemistry over the fuse and, optionally, a diffusion barrier layer immediately over the fuse. The lower etch-stop later and the optional diffusion barrier providing a uniform passivation thickness for use in conjunction with laser fuse deletion processes. An upper etch-resistant layer over the lower etch-resistant layer and having an etch chemistry selective to that of the lower etch-resistant layer. Methods for providing a uniform passivation thickness over all the fuses, and for deleting such fuses.

Abstract: A method and apparatus are provided for laser fuseblow protection in transistors, such as silicon-on-insulator (SOI) transistors. The transistors are connected to a fuse. A pair of diodes are connected in series between a high supply and ground. A common connection of the series connected pair of diodes is connected to a common connection of the fuse and transistors. A charge is shunted to the high supply or ground by the pair of diodes with a first voltage a set value above the high supply and a second voltage a set value below the ground. A pair of protection diodes are provided on each side of the fuse with transistors. The transistors are either connected to one side of the fuse or to both sides of the fuse.

Abstract: A fuse area structure in a semiconductor device and a method of forming the same are provided. A ring-shaped guard ring which surrounds a fuse opening, for preventing moisture from seeping into the side surface of the exposed fuse opening, is included. The guard ring is integrally formed with a passivation film. In order to form the guard ring, a guard ring opening etching stop film is formed on a fuse line. A guard ring opening is formed using the etching stop film, and a contact hole is formed in a peripheral circuit. A conductive material layer for forming an upper interconnection layer is formed on the entire surface of a resultant structure on which the contact hole and the guard ring opening are formed. The conductive material layer formed on the guard ring opening is removed. The exposed etching stop film is removed. Finally, a passivation film is deposited on the entire surface of the resulting structure.

Abstract: An integrated circuit structure for MOS-type devices comprising a silicon substrate of a first conductivity type; a first gate insulating regions selectively placed over the silicon substrate of the first conductivity type; a first polycrystalline silicon layer selectively placed over the silicon substrate of the first conductivity type; a second gate insulating regions selectively placed over the first gate insulating regions and the first polycrystalline silicon layer; a second polycrystalline silicon layer selectively placed over the second gate insulating regions; first buried silicon regions of a second conductivity type, buried within the silicon substrate of the first conductivity type, placed under the first polycrystalline silicon layer and in contact therewith; and second buried silicon regions of the second conductivity type, buried within the silicon substrate of the first conductivity type, placed under the second gate insulating regions, under the second polycrystalline silicon layer and insulat

Abstract: A new cascaded NMOS transistor output circuit with enhanced ESD protection is achieved. A driver PMOS transistor has the source connected to a voltage supply, the gate connected to the input signal, and the drain connected to the output pad. A dummy PMOS transistor has the source and the gate connected to the voltage supply, and the drain connected to the output pad. A driver NMOS cascaded stack comprises first and second NMOS transistors. The first NMOS transistor has the source connected to ground and the gate connected to the input signal. The second NMOS transistor has the gate connected to the voltage supply, the source connected to the first NMOS transistor drain, and the drain connected to the output pad. A p− implanted region underlies the n+ region of the drain but does not underlie the n+ region of the source. A dummy NMOS cascaded stack comprises third and fourth NMOS transistors. The third NMOS transistor has the gate and the source connected to ground.

Abstract: A fusible link for a semiconductor device comprises an insulating substrate and a conductive line pair on the surface of the insulating substrate, with the conductive line pair having spaced ends. A polymer is disposed over the insulating substrate and between the conductive line pair ends. The polymer is capable of being changed from a non-conductive to a conductive state upon exposure to an energy beam. Preferably, the polymer comprises a polyimide, more preferably, a polymer/onium salt mixture, most preferably, a polyaniline polymer doped with a triphenylsufonium salt. The link may further comprise a low k nanopore/nanofoam dielectric material adjacent the conductive line ends.

Abstract: The semiconductor device includes a semiconductor substrate, an insulating layer on the semiconductor substrate wherein a groove is patterned to a predetermined depth in an upper surface of the insulating layer, a fuse layer at sidewalls and on a bottom of the groove, and a wire connected electrically to the fuse layer.

Abstract: The tradeoff between breakdown voltage and on-resistance for LDMOS devices has been improved by having two epitaxial N− regions instead of the single epitaxial N− region that is used by devices of the prior art. The resistivities and thicknesses of these two N− regions are chosen so that their mean resistivity is similar to that of the aforementioned single N− layer. A key feature is that the lower N− layer (i.e. the one closest to the P− substrate) has a resistivity that is greater than that of the upper N− layer. If these constraints are met, as described in greater detail in the specification, improvements in breakdown voltage of up to 60% can be achieved without having to increase the on resistance. A process for manufacturing the device is also described.