Abstract: The disclosed technology relates to a semiconductor integrated circuit that comprises a semiconductor device which has a port to be protected from Plasma-Induced Damage due to electric charge that may accumulate at the port during a plasma-processing step, and a protection circuit that is provided to the integrated circuit. In one aspect, the protection circuit comprises a discharge path, a control terminal, and a plasma pick-up antenna connected to the control terminal. The protection circuit further comprises a bipolar transistor which has a base connected to the control terminal. Such protection circuit is much more efficient in allowing charge transfer from the device port to a reference voltage terminal.

Abstract: Systems, methods, circuits, and apparatus including computer-readable mediums for protecting memory cells from in-process charging effects for a memory system, e.g., NAND flash memory. The methods include: forming a first connection to connect a first node of a diode to a memory cell line coupled with one or more memory cells to be fabricated and a second connection to connect a second node of the diode to a control circuit, such that, during fabricating the memory, in-process charges accumulated on the memory cells are discharged to a ground via a conductive path formed by a first voltage caused by the in-process charges forward biasing the diode and then enabling the control circuit to conduct a current to the ground, and after fabricating the memory and during operating the memory, turning off the conductive path by reverse biasing the diode with a second voltage applied on the control circuit.

Abstract: The present invention relates to an organic light emitting device and a method for preparing the same. An organic light emitting device according to the present invention comprises an organic light emitting unit having a structure in which a substrate, a first electrode, an organic material layer, and a second electrode are sequentially laminated, wherein the organic light emitting device comprises an auxiliary electrode and a fuse pattern; and the first electrode and the auxiliary electrode are electrically connected to each other through the fuse pattern.

Abstract: A differential port and a method of arranging the differential port are described. The method includes arranging a first electrode to receive a drive signal, and arranging a second electrode to receive a guard signal, the guard signal having a different phase than the drive signal and the first electrode and the second electrode having a gap therebetween. The method also includes disposing a signal line from the first electrode to drive a radio frequency (RF) device.

Abstract: According to one embodiment, a one-time programmable (OTP) semiconductor device includes a programming dielectric under a patterned electrode and over an implant region, where the programming dielectric forms a programming region of the OTP semiconductor device. The OTP semiconductor device further includes an isolation region laterally separating the programming dielectric from a coupled semiconductor structure, where the isolation region can be used in conjunction with the patterned electrode and the implant region to protect the coupled semiconductor structure. In one embodiment, the programming dielectric comprises a gate dielectric. In another embodiment, the electrode and implant regions are doped to be electrochemically similar.

Abstract: A method of forming an electronic fuse including providing an Mx level including a first Mx metal, a second Mx metal, and an Mx cap dielectric above of the first and second Mx metal, forming an Mx+1 level above the Mx level, the Mx+1 level including an Mx+1 metal and a via electrically connecting the second Mx metal to the Mx+1 metal in a vertical orientation, and forming a nano-pillar from the Mx cap dielectric at a bottom of the via and above the second Mx metal, the nano-pillar having a height less than a height of the via.

Abstract: An electronic fuse structure having an Mx level including an Mx dielectric, a fuse line, an Mx cap dielectric above at least a portion of the Mx dielectric, and a modified portion of the Mx cap dielectric directly above at least a portion of the fuse line, where the modified portion of the Mx cap dielectric is chemically different from the remainder of the Mx cap dielectric, an Mx+1 level including an Mx+1 dielectric, a first Mx+1 metal, an Mx+1 cap dielectric above of the Mx+1 dielectric and the first Mx+1 metal, where the Mx+1 level is above the Mx level, and a first via electrically connecting the fuse line to the first Mx+1 metal.

Abstract: As for a memory element implemented in a semiconductor device typified by an RFID, it is an object of the present invention to reduce manufacturing steps and to provide a memory element and a memory circuit having the element with reduced cost. It is a feature of the present invention that a memory element sandwiched between electrodes has an organic compound, and an electrode connected to a semiconductor element controlling the memory element functions as an electrode of the memory element. In addition, an extremely thin semiconductor film formed on an insulated surface is used for the memory element; therefore cost can be reduced.

Abstract: An electrically reprogrammable fuse comprising an interconnect disposed in a dielectric material, a sensing wire disposed at a first end of the interconnect, a first programming wire disposed at a second end of the interconnect, and a second programming wire disposed at a second end of the interconnect, wherein the fuse is operative to form a surface void at the interface between the interconnect and the sensing wire when a first directional electron current is applied from the first programming wire through the interconnect to the second programming wire, and wherein, the fuse is further operative to heal the surface void between the interconnect and the sensing wire when a second directional electron current is applied from the second programming wire through the interconnect to the first programming wire.

Abstract: A differential port and a method of arranging the differential port are described. The method includes arranging a first electrode to receive a drive signal, and arranging a second electrode to receive a guard signal, the guard signal having a different phase than the drive signal and the first electrode and the second electrode having a gap therebetween. The method also includes disposing a signal line from the first electrode to drive a radio frequency (RF) device.

Abstract: In one general aspect, an apparatus can include a semiconductor substrate, and a first conductive fuse bus having a triangular-shaped portion with a bottom surface aligned along a plane substantially parallel to a surface of the semiconductor substrate. The apparatus can include a second conductive fuse bus having a bottom surface aligned along the plane, and a plurality of fuse links coupled between the triangular-shaped portion of the first conductive fuse bus and the second conductive fuse bus.

Abstract: A method for performing silicidation of a gate electrode is provided that includes forming both a first transistor with a first gate electrode covered by a cap layer and a semiconductor device on the same semiconductor substrate, forming an organic planarization layer (OPL) on the first transistor and the semiconductor device, back etching the OPL such that an upper surface of the OPL is positioned at a level that is below a level of an upper surface of the cap layer, forming a mask layer covering the semiconductor device without covering the first transistor, removing the cap layer while the back-etched OPL and the mask layer are present, and performing silicidation of the first gate electrode.

Abstract: An e-fuse structure and method has an anode; a fuse link (a first end of the fuse link is connected to the anode); a cathode (a second end of the fuse link opposite the first end is connected to the cathode); and a silicide layer on the fuse link. The silicide layer has a first silicide region adjacent the anode and a second silicide region adjacent the cathode. The second silicide region comprises an impurity not contained within the first silicide region. Further, the first silicide region is thinner than the second silicide region.

Abstract: An e-fuse structure and method has an anode; a fuse link (a first end of the fuse link is connected to the anode); a cathode (a second end of the fuse link opposite the first end is connected to the cathode); and a silicide layer on the fuse link. The silicide layer has a first silicide region adjacent the anode and a second silicide region adjacent the cathode. The second silicide region comprises an impurity not contained within the first silicide region. Further, the first silicide region is thinner than the second silicide region.

Abstract: A semiconductor device has a field insulating film provided on a semiconductor substrate, and a fuse provided on the field insulating film and having a fuse trimming laser irradiation portion and fuse terminals. The semiconductor device further includes an intermediate insulating film covering the fuse, a first TEOS layer on the intermediate insulating film, an SOG layer for planarizing the first TEOS layer, a second TEOS layer on the SOG layer and on the first TEOS layer, a protective film on the second TEOS layer, and an opening portion above the fuse trimming laser irradiation portion in a region from the protective film to the first TEOS layer. A seal ring is provided on the intermediate insulating film so as to surround the opening portion. The seal ring is disposed over the fuse so as to overlap each of the fuse terminals in plan view.

Abstract: A method of forming a semiconductor device includes forming a field-effect transistor (FET), and forming a fuse which includes a graphene layer and is electrically connected to the FET.

Abstract: The invention relates generally to a fuse device of a semiconductor device, and more particularly, to an electrical fuse device of a semiconductor device. Embodiments of the invention provide a fuse device that is capable of reducing programming error caused by non-uniform current densities in a fuse link. In one respect, there is provided an electrical fuse device that includes: an anode; a fuse link coupled to the anode on a first side of the fuse link; a cathode coupled to the fuse link on a second side of the fuse link; a first cathode contact coupled to the cathode; and a first anode contact coupled to the anode, at least one of the first cathode contact and the first anode contact being disposed across a virtual extending surface of the fuse link.

Abstract: An electrically reprogrammable fuse comprising an interconnect disposed in a dielectric material, a sensing wire disposed at a first end of the interconnect, a first programming wire disposed at a second end of the interconnect, and a second programming wire disposed at a second end of the interconnect, wherein the fuse is operative to form a surface void at the interface between the interconnect and the sensing wire when a first directional electron current is applied from the first programming wire through the interconnect to the second programming wire, and wherein, the fuse is further operative to heal the surface void between the interconnect and the sensing wire when a second directional electron current is applied from the second programming wire through the interconnect to the first programming wire.

Abstract: A fabrication method for fabricating an electrically programmable fuse method includes depositing a polysilicon layer on a substrate, patterning an anode contact region, a cathode contact region and a fuse link conductively connecting the cathode contact region with the anode contact region, which is programmable by applying a programming current, depositing a silicide layer on the polysilicon layer, and forming a plurality of anisometric contacts on the silicide layer of the cathode contact region and the anode contact region in a predetermined configuration, respectively.

Abstract: A semiconductor-based electronic fuse may be provided in a sophisticated semiconductor device having a bulk configuration by appropriately embedding the electronic fuse into a semiconductor material of reduced heat conductivity. For example, a silicon/germanium fuse region may be provided in the silicon base material. Consequently, sophisticated gate electrode structures may be formed on the basis of replacement gate approaches on bulk devices substantially without affecting the electronic characteristics of the electronic fuses.

Abstract: A semiconductor device includes: an e-fuse gate, a floating pattern between the e-fuse gate and an e-fuse active portion, a blocking dielectric pattern between the floating pattern and the e-fuse gate, and an e-fuse dielectric layer between the floating pattern and the e-fuse active portion. The floating pattern includes a first portion between the e-fuse gate and the e-fuse active portion and a pair of second portions extended upward along both sidewalls of the e-fuse gate from both edges of the first portion.

Abstract: An electrically reprogrammable fuse comprising an interconnect disposed in a dielectric material, a sensing wire disposed at a first end of the interconnect, a first programming wire disposed at a second end of the interconnect, and a second programming wire disposed at a second end of the interconnect, wherein the fuse is operative to form a surface void at the interface between the interconnect and the sensing wire when a first directional electron current is applied from the first programming wire through the interconnect to the second programming wire, and wherein, the fuse is further operative to heal the surface void between the interconnect and the sensing wire when a second directional electron current is applied from the second programming wire through the interconnect to the first programming wire.

Abstract: The present invention provides fuse patterns and a method of manufacturing the same. According to the present invention, an insulating layer and a contact plug are filled between fuse patterns which are formed to have their ends broken and are isolated from each other. In case of a fail cell, the insulating layer is broken owing a difference in an electrical bias (current or voltage) between a metal wire and the fuse patterns, and a short is generated between the fuse patterns. Accordingly, embodiments avoid damage to a semiconductor substrate associated with a conventional fuse repair method employing laser energy, and the area of a fuse box can be reduced.

Abstract: Techniques for incorporating nanotechnology into electronic fuse (e-fuse) designs are provided. In one aspect, an e-fuse structure is provided. The e-fuse structure includes a first electrode; a dielectric layer on the first electrode having a plurality of nanochannels therein; an array of metal silicide nanopillars that fill the nanochannels in the dielectric layer, each nanopillar in the array serving as an e-fuse element; and a second electrode in contact with the array of metal silicide nanopillars opposite the first electrode. Methods for fabricating the e-fuse structure are also provided as are semiconductor devices incorporating the e-fuse structure.

Abstract: A semiconductor device includes a semiconductor substrate, a base insulating layer, a silicon fuse, a pair of silicon wires, a silicon guard ring, an insulation coating, a first interlayer insulating layer, a via guard ring, a metal guard ring, a final insulating layer, and a fuse window. The base insulating layer is disposed over the semiconductor substrate. The silicon fuse is disposed on the base insulating layer. The pair of silicon wires is disposed on the base insulating layer. The silicon guard ring is disposed on the base insulating layer. The insulation coating is deposited at least over surfaces of the silicon wires. The first interlayer insulating layer is disposed on the base insulating layer. The final insulating layer is disposed on the interlayer insulating layer. The fuse window is defined above the silicon fuse inside the guard rings.

Abstract: A security chip is disclosed. The security chip includes: a substrate; an integrated circuit disposed on the substrate, the integrated circuit including circuit elements, circuit interconnect layers connecting the circuit elements together, and interlayer contacts supporting the circuit interconnect layers; a shield to at least partially shield the integrated circuit; and at least one lightwell in the shield and the integrated circuit, wherein each lightwell has a closed shape formed from parts of the circuit interconnect layers and interlayer contacts, wherein no exploitable voltage can be measured on the parts of the circuit interconnect layers and interlayer contacts, and wherein each lightwell forms a path for light to penetrate to the substrate preventing the light from reaching the circuit elements. Related apparatus and methods are also disclosed.

Abstract: A fuse part for a semiconductor device includes an insulation layer configured to cover a conductive pattern over a substrate, a dual fuse configured to include a first pattern and a second pattern that are positioned on the same line over the insulation layer and spaced apart from each other by a certain distance, a protective layer configured to cover the dual fuse and include a first fuse box and a second fuse box that partially expose the first pattern and the second pattern, respectively, and a plurality of plugs configured to penetrate the insulation layer and electrically connect the first and second patterns to the conductive pattern. Herein, the plugs are positioned beneath the first and second fuse boxes.

Abstract: The present invention provides a method of integrating an electrical fuse process into a high-k/metal gate process. The method simultaneously forms a dummy gate stack of a transistor and a dummy gate stack of an e-fuse; and simultaneously removes the polysilicon of the dummy gate stack in the transistor region and the polysilicon of the dummy gate stack in the e-fuse region. Thereafter, the work function metal layer disposed in the opening of the e-fuse region is removed; and the opening in the transistor region and the opening in the e-fuse region with metal conductive structures are filled to form an e-fuse and a metal gate of a transistor.

Abstract: In a replacement gate approach, the semiconductor material of the gate electrode structures may be efficiently removed during a wet chemical etch process, while this material may be substantially preserved in electronic fuses. Consequently, well-established semiconductor-based electronic fuses may be used instead of requiring sophisticated metal-based fuse structures. The etch selectivity of the semiconductor material may be modified on the basis of ion implantation or electron bombardment.

Abstract: A method is provided for fabricating an electrical fuse and a field effect transistor having a metal gate which includes removing material from first and second openings in a dielectric region overlying a substrate, wherein the first opening is aligned with an active semiconductor region of the substrate, and the second opening is aligned with an isolation region of the substrate, and the active semiconductor region including a source region and a drain region adjacent edges of the first opening. An electrical fuse can be formed which has a fuse element filling the second opening, the fuse element being a monolithic region of a single conductive material being a metal or a conductive compound of a metal. A metal gate can be formed which extends within the first opening to define a field effect transistor (“FET”) which includes the metal gate and the active semiconductor region.

Abstract: Techniques for incorporating nanotechnology into electronic fuse (e-fuse) designs are provided. In one aspect, an e-fuse structure is provided. The e-fuse structure includes a first electrode; a dielectric layer on the first electrode having a plurality of nanochannels therein; an array of metal silicide nanopillars that fill the nanochannels in the dielectric layer, each nanopillar in the array serving as an e-fuse element; and a second electrode in contact with the array of metal silicide nanopillars opposite the first electrode. Methods for fabricating the e-fuse structure are also provided as are semiconductor devices incorporating the e-fuse structure.

Abstract: A semiconductor device includes an electric fuse formed on a substrate. The electric fuse includes: a first interconnect formed on one end side thereof; a second interconnect formed in a layer different from a layer in which the first interconnect is formed; a first via provided in contact with the first interconnect and the second interconnect to connect those interconnects; a third interconnect formed on another end side thereof, the third interconnect being formed in the same layer in which the first interconnect is formed, as being separated from the first interconnect; and a second via provided in contact with the third interconnect and the second interconnect to connect those interconnects, the second via being lower in resistance than the first via. The electric fuse is disconnected by a flowing-out portion to be formed of a conductive material forming the electric fuse which flows outwardly during disconnection.

Abstract: An electrical fuse has an anode contact on a surface of a semiconductor substrate. The electrical fuse has a cathode contact on the surface of the semiconductor substrate spaced from the anode contact. The electrical fuse has a link within the substrate electrically interconnecting the anode contact and the cathode contact. The link comprises a semiconductor layer and a silicide layer. The silicide layer extends beyond the anode contact. An opposite end of the silicide layer extends beyond the cathode contact. A silicon germanium region is embedded in the semiconductor layer under the silicide layer, between the anode contact and the cathode contact.

Abstract: A copper-compatible fuse target is fabricated by forming a target structure at the same time that a trace structure is formed on a passivation layer, followed by the formation of an overlying non-conductive structure. After the overlying non-conductive structure has been formed, a passivation opening is formed in the non-conductive structure to expose the passivation layer and the side wall of the target structure.

Abstract: In sophisticated integrated circuits, an electronic fuse may be formed such that an increased sensitivity to electromigration may be accomplished by including at least one region of increased current density. This may be accomplished by forming a corresponding fuse region as a non-linear configuration, wherein at corresponding connection portions of linear segments, the desired enhanced current crowding may occur during the application of the programming voltage. Hence, increased reliability and more space-efficient layout of the electronic fuses may be accomplished.

Abstract: A semiconductor device includes an electric fuse formed on a semiconductor substrate and composed of an electric conductor. The electric fuse includes an upper layer interconnect, a via coupled to the upper interconnect and a lower layer interconnect coupled to the via, which are formed in different layers, respectively, in a condition before cutting the electric fuse, and wherein the electric fuse includes a flowing-out region formed of the electric conductor being flowed toward outside from the second interconnect and a void region formed between the first interconnect and the via or in the via, in a condition after cutting the electric fuse.

Abstract: A fuse element is laminated on a resistor and the resistor is formed in a concave shape below a region in which cutting of the fuse element is carried out with a laser. Accordingly, there can be provided a semiconductor device which occupies a small area, causes no damage on the resistor in the cutting of the fuse element, has a small contact resistance occurred between elements, and has stable characteristics, and a method of manufacturing the same.

Abstract: A dielectric material layer is formed on a metal gate layer for a metal gate electrode, and then lithographically patterned to form a dielectric material portion, followed by formation of a polycrystalline semiconductor layer thereupon. A semiconductor device employing a metal gate electrode is formed in a region of the semiconductor substrate containing a vertically abutting stack of the metal gate layer and the polycrystalline semiconductor layer. A material stack in the shape of an electrical fuse is formed in another region of the semiconductor substrate containing a vertical stack of the metal gate layer, the dielectric material portion, and the polycrystalline semiconductor layer. After metallization of the polycrystalline semiconductor layer, an electrical fuse containing a polycrystalline semiconductor portion and a metal semiconductor alloy portion is formed over the dielectric material portion that separates the electrical fuse from the metal gate layer.

Abstract: A method and structure to scale metal gate height in high-k/metal gate transistors. A method includes forming a dummy gate and at least one polysilicon feature, all of which are formed from a same polysilicon layer and wherein the dummy gate is formed over a gate metal layer associated with a transistor. The method also includes selectively removing the dummy gate while protecting the at least one polysilicon feature. The method further includes forming a gate contact on the gate metal layer to thereby form a metal gate having a height that is less than half a height of the at least one polysilicon feature.

Abstract: A semiconductor structure is provided that includes an interconnect structure and a fuse structure located in different areas, yet within the same interconnect level. The interconnect structure has high electromigration resistance, while the fuse structure has a lower electromigration resistance as compared with the interconnect structure. The fuse structure includes a conductive material embedded within an interconnect dielectric in which the upper surface of the conductive material has a high concentration of oxygen present therein. A dielectric capping layer is located atop the dielectric material and the conductive material. The presence of the surface oxide layer at the interface between the conductive material and the dielectric capping layer degrades the adhesion between the conductive material and the dielectric capping layer.

Abstract: The present invention relates to electrostatic discharge (ESD) protection circuitry. Multiple techniques are presented to adjust one or more ends of one or more fingers of an ESD protection device so that the ends of the fingers have a reduced initial trigger or breakdown voltage as compared to other portions of the fingers, and in particular to central portions of the fingers. In this manner, most, if not all, of the adjusted ends of the fingers are likely to trigger or fire before any of the respective fingers completely enters a snapback region and begins to conduct ESD current. Consequently, the ESD current is more likely to be distributed among all or substantially all of the plurality of fingers rather than be concentrated within one or merely a few fingers. As a result, potential harm to the ESD protection device (e.g., from current crowding) is mitigated and the effectiveness of the device is improved.

Abstract: A programmable anti-fuse element includes a substrate (224), an N-well (426) in the substrate, an electrically insulating layer (427) over the N-well, and a gate electrode (430) over the electrically insulating layer. The gate electrode has n-type doping so that the N-well is able to substantially contain within its boundaries a current generated following a programming event of the programmable anti-fuse element. In the same or another embodiment, a twice-programmable fuse element (100) includes a metal gate fuse (110) and an oxide anti-fuse (120) such as the programmable anti-fuse element just described.

Abstract: A semiconductor device includes an electric fuse and first and second large area wirings for applying a voltage to the electric fuse. The electric fuse includes a fuse unit which includes an upper-layer fuse wiring, a lower-layer fuse wiring, and a via connecting the upper-layer fuse wiring and the lower-layer fuse wiring, an upper-layer lead-out wiring which connects the upper-layer fuse wiring and the first large area wiring and has a bent pattern, and a lower-layer lead-out wiring which connects the lower-layer fuse wiring and the second large area wiring and has a bent pattern.

Abstract: The invention includes semiconductor fuse arrangements containing an electrically conductive plate over and in electrical contact with a plurality of electrically conductive links. Each of the links contacts the electrically conductive plate as a separate region relative to the other links, and the region where a link makes contact to the electrically conductive plate is a fuse. The invention also includes methods of forming semiconductor fuse arrangements.

Abstract: The present invention provides a laminate comprising an insulating layer having suppressed dusting properties, an insulating film comprising the insulating layer, and an electronic circuit component comprising a pattern of the insulating layer. The laminate has a layer construction of first inorganic material layer-insulating layer-second inorganic material layer or a layer construction of inorganic material layer-insulating layer. The insulating layer comprises a laminate of two or more wet etchable insulating unit layers. At the interface between the inorganic material layer and the insulating layer, surface irregularities of the inorganic material layer have been transferred onto the surface of the insulating layer. The average height of the surface irregularities transferred onto the insulating layer is less than the thickness of the outermost insulating unit layer in the insulating layer.

Abstract: The invention relates generally to a fuse device of a semiconductor device, and more particularly, to an electrical fuse device of a semiconductor device. Embodiments of the invention provide a fuse device that is capable of reducing programming error caused by non-uniform current densities in a fuse link. In one respect, there is provided an electrical fuse device that includes: an anode; a fuse link coupled to the anode on a first side of the fuse link; a cathode coupled to the fuse link on a second side of the fuse link; a first cathode contact coupled to the cathode; and a first anode contact coupled to the anode, at least one of the first cathode contact and the first anode contact being disposed across a virtual extending surface of the fuse link.

Abstract: An electrically programmable fuse includes an anode, a cathode, and a fuse link conductively connecting the cathode with the anode, which is programmable by applying a programming current. The anode and the fuse link each include a polysilicon layer and a silicide layer formed on the polysilicon layer, and the cathode includes the polysilicon layer and a partial silicide layer formed on a predetermined portion of the polysilicon layer of the cathode located adjacent to a cathode junction where the cathode and the fuse link meet.

Abstract: A method of cutting an electrical fuse including a first conductor and a second conductor, the first conductor including a first cutting target region, the second conductor branched from the first conductor and connected to the first conductor and including a second cutting target region, which are formed on a semiconductor substrate, the method includes flowing a current in the first conductor, causing material of the first conductor to flow outward near a coupling portion connecting the first conductor to the second conductor, and cutting the first cutting target region and the second cutting target region.

Abstract: The present invention provides antifuse structures having an integrated heating element and methods of programming the same, the antifuse structures comprising first and second conductors and a dielectric layer formed between the conductors, where one or both of the conductors functions as both a conventional antifuse conductor and as a heating element for directly heating the antifuse dielectric layer during programming.

Abstract: A repair fuse element and method of construction are disclosed that eliminate or substantially reduce the disadvantages and problems associated with prior fuse elements. In one embodiment, the fuse element is constructed with a rectangular-shaped contact. The contact is made long enough so that it makes contact at each end with a metal layer, but design rule spacing is still maintained between the connections with the metal layer. The overlapping areas between the rectangular contact and the metal layers are asymmetrical. Alternatively, these overlapping areas are smaller than the design rule overlap requirements. In a second embodiment, a fuse element is constructed with a plurality of rectangular-shaped contacts. As a result, a current value that is significantly lower than conventional fuse current values, can be used to melt such a contact or blow the fuse.