Abstract: An integrated circuit includes a semiconductor substrate with an electrically isolated semiconductor well. An upper trench isolation extends from a front face of the semiconductor well to a depth located a distance from the bottom of the well. Two additional isolating zones are electrically insulated from the semiconductor well and extending inside the semiconductor well in a first direction and vertically from the front face to the bottom of the semiconductor well. At least one hemmed resistive region is bounded by the two additional isolating zones, the upper trench isolation and the bottom of the semiconductor well. Electrical contacts are electrically coupled to the hemmed resistive region.

Abstract: Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer.

Abstract: In an example, a single damascene structure is formed by, for example, providing a dielectric layer, forming a void in the dielectric layer, and forming a portion of a first two-terminal resistive memory cell and a portion of a second two-terminal resistive memory cell within the void. The portions of the two-terminal resistive memory cells may be vertically stacked within the void.

Abstract: A resistor structure incorporated into a resistive switching memory cell or device to form memory devices with improved device performance and lifetime is provided. The resistor structure may be a two-terminal structure designed to reduce the maximum current flowing through a memory device. A method is also provided for making such memory device. The method includes depositing a resistor structure and depositing a variable resistance layer of a resistive switching memory cell of the memory device, where the resistor structure is disposed in series with the variable resistance layer to limit the switching current of the memory device. The incorporation of the resistor structure is very useful in obtaining desirable levels of device switching currents that meet the switching specification of various types of memory devices. The memory devices may be formed as part of a high-capacity nonvolatile memory integrated circuit, which can be used in various electronic devices.

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

Abstract: A nonvolatile semiconductor memory device includes: a semiconductor member; a memory film provided on a surface of the semiconductor member and being capable of storing charge; and a plurality of control gate electrodes provided on the memory film, spaced from each other, and arranged along a direction parallel to the surface. Average dielectric constant of a material interposed between one of the control gate electrodes and a portion of the semiconductor member located immediately below the control gate electrode adjacent to the one control gate electrode is lower than average dielectric constant of a material interposed between the one control gate electrode and a portion of the semiconductor member located immediately below the one control gate electrode.

Abstract: A resistor structure incorporated into a resistive switching memory cell or device to form memory devices with improved device performance and lifetime is provided. The resistor structure may be a two-terminal structure designed to reduce the maximum current flowing through a memory device. A method is also provided for making such memory device. The method includes depositing a resistor structure and depositing a variable resistance layer of a resistive switching memory cell of the memory device, where the resistor structure is disposed in series with the variable resistance layer to limit the switching current of the memory device. The incorporation of the resistor structure is very useful in obtaining desirable levels of device switching currents that meet the switching specification of various types of memory devices. The memory devices may be formed as part of a high-capacity nonvolatile memory integrated circuit, which can be used in various electronic devices.

Abstract: Semiconductor structures with high impedances for use in biasing for applying voltage bias to part of a device. The semiconductor structure comprises a continuous structure having a plurality of regions of a first semiconductor type (n type or p type) material arranged alternately with at least one region of the opposite type. The structure may be formed from polysilicon and may also include a plurality of intrinsic regions arranged between the n and p type regions. The structure forms a composite diode and provides a high impedance.

Abstract: Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer.

Abstract: A resistor structure incorporated into a resistive switching memory cell or device to form memory devices with improved device performance and lifetime is provided. The resistor structure may be a two-terminal structure designed to reduce the maximum current flowing through a memory device. A method is also provided for making such memory device. The method includes depositing a resistor structure and depositing a variable resistance layer of a resistive switching memory cell of the memory device, where the resistor structure is disposed in series with the variable resistance layer to limit the switching current of the memory device. The incorporation of the resistor structure is very useful in obtaining desirable levels of device switching currents that meet the switching specification of various types of memory devices. The memory devices may be formed as part of a high-capacity nonvolatile memory integrated circuit, which can be used in various electronic devices.

Abstract: A meander line resistor structure comprises a first resistor formed on a first active region, wherein the first resistor is formed by a plurality of first vias connected in series, a second resistor formed on a second active region, wherein the second resistor is formed by a plurality of second vias connected in series and a third resistor formed on the second active region, wherein the third resistor is formed by a plurality of third vias connected in series. The meander line resistor further comprises a first connector coupled between the first resistor and the second resistor.

Abstract: A variable resistive element comprising a configuration that an area of an electrically contributing region of a variable resistor body is finer than that constrained by an upper electrode or a lower electrode and its manufacturing method are provided. A bump electrode material is formed on a lower electrode arranged on a base substrate. The bump electrode material is contacted to a variable resistor body at a surface different from a contact surface to the lower electrode. The variable resistor body is contacted to an upper electrode at a surface different from a contact surface to the bump electrode material. Thus, a cross point region between the bump electrode material (the variable resistor body) and the upper electrode becomes an electrically contributing region of the variable resistor body, and then an area thereof can be reduced compared with that of the region regarding the conventional variable resistive element.

Abstract: Electron mobility and hole mobility is improved in long channel semiconductor devices and resistors by employing complementary stress liners. Embodiments include forming a long channel semiconductor device on a substrate, and forming a complementary stress liner on the semiconductor device. Embodiments include forming a resistor on a substrate, and tuning the resistance of the resistor by forming a complementary stress liner on the resistor. Compressive stress liners are employed for improving electron mobility in n-type devices, and tensile stress liners are employed for improving hole mobility in p-type devices.

Abstract: Provided is a high voltage semiconductor device that includes a PIN diode structure formed in a substrate. The PIN diode includes an intrinsic region located between a first doped well and a second doped well. The first and second doped wells have opposite doping polarities and greater doping concentration levels than the intrinsic region. The semiconductor device includes an insulating structure formed over a portion of the first doped well. The semiconductor device includes an elongate resistor device formed over the insulating structure. The resistor device has first and second portions disposed at opposite ends of the resistor device, respectively. The semiconductor device includes an interconnect structure formed over the resistor device. The interconnect structure includes: a first contact that is electrically coupled to the first doped well and a second contact that is electrically coupled to a third portion of the resistor located between the first and second portions.

Abstract: A memristor includes a first electrode of a nanoscale width; a second electrode of a nanoscale width; and an active region disposed between the first and second electrodes. The active region has a both a non-conducting portion and a source of dopants portion induced by electric field. The non-conducting portion comprises an electronically semiconducting or nominally insulating material and a weak ionic conductor switching material capable of carrying a species of dopants and transporting the dopants under an electric field. The non-conducting portion is in contact with the first electrode and the source of dopants portion is in contact with the second electrode. The second electrode comprises a metal reservoir for the dopants. A crossbar array comprising a plurality of the nanoscale switching devices is also provided. A process for making at least one nanoscale switching device is further provided.

Abstract: Provided is a high voltage semiconductor device. The semiconductor device includes a doped well located in a substrate that is oppositely doped. The semiconductor device includes a dielectric structure located on the doped well. A portion of the doped well adjacent the dielectric structure has a higher doping concentration than a remaining portion of the doped well. The semiconductor device includes an elongate polysilicon structure located on the dielectric structure. The elongate polysilicon structure has a length L. The portion of the doped well adjacent the dielectric structure is electrically coupled to a segment of the elongate polysilicon structure that is located away from a midpoint of the elongate polysilicon structure by a predetermined distance that is measured along the elongate polysilicon structure. The predetermined distance is in a range from about 0*L to about 0.1*L.

Abstract: A structure including at least two neighboring components, capable of operating at high frequencies, formed in a thin silicon substrate extending on a silicon support and separated therefrom by an insulating layer, the components being laterally separated by insulating regions. The silicon support has, at least in the vicinity of its portion in contact with the insulating layer, a resistivity greater than or equal to 1,000 ohms.cm.

Abstract: A method of forming a semiconductor structure includes forming a resistor on an insulator layer over a substrate and forming a trench in the resistor and into the substrate. The method also includes forming a liner on sidewalls of the trench and forming a core comprising a high thermal conductivity material in the trench and on the liner.

Abstract: Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer.

Abstract: Methods of fabricating a passive element and a semiconductor device including the passive element are disclosed including the use of a dummy passive element. A dummy passive element is a passive element or wire which is added to the chip layout to aid in planarization but is not used in the active circuit. One embodiment of the method includes forming the passive element and a dummy passive element adjacent to the passive element; forming a dielectric layer over the passive element and the dummy passive element, wherein the dielectric layer is substantially planar between the passive element and the dummy passive element; and forming in the dielectric layer an interconnect to the passive element through the dielectric layer and a dummy interconnect portion overlapping at least a portion of the dummy passive element. The methods eliminate the need for planarizing.

Abstract: A method of forming a semiconductor structure includes: forming a resistor over a substrate; forming at least one first contact in contact with the resistor; and forming at least one second contact in contact with the resistor. The resistor is structured and arranged such that current flows from the at least one first contact to the at least one second contact through a central portion of the resistor. The resistor includes at least one extension extending laterally outward from the central portion in a direction parallel to the current flow. The method includes sizing the at least one extension based on a thermal diffusion length of the resistor.

Abstract: Provided are a non-volatile memory device which can be extended in a stack structure and thus can be highly integrated, and a method of manufacturing the non-volatile memory device. The non-volatile memory device includes: at least one first electrode, at least one second electrode crossing the at least one first electrode, at least one data storing layer interposed between the at least one first electrode and the second electrode, at a region in which the at least one first electrode crosses the at least one second electrode and at least one metal silicide layer interposed between the at least one first electrode and the at least one second electrode, at the region in which the at least one first electrode crosses the at least one second electrode.

Abstract: A semiconductor device of the invention has a plurality of resistor elements formed on an element isolating oxide film in predetermined regions on a surface of a semiconductor substrate. Active regions are furnished close to the resistor elements. This allows the element isolating oxide film near the resistor elements to be divided into suitable strips, forestalling a concave formation at the center of the element isolating oxide film upon polishing of the film by CMP and thereby enhancing dimensional accuracy of the resistor elements upon fabrication.

Abstract: A silicide-interface polysilicon resistor is disclosed. The silicide-interface polysilicon resistor includes a substrate, an oxide layer located on top of the substrate, and a polysilicon layer located on top of the oxide layer. The polysilicon layer includes multiple semiconductor junctions. The silicide-interface polysilicon resistor also includes a layer of silicide sheets, and at least one of the silicon sheets is in contact with one of the semiconductor junctions located within the polysilicon layer.

Abstract: A method of fabricating a semiconductor-on-insulator device including: providing a first semiconductor wafer having an about 500 angstrom thick oxide layer thereover; etching the first semiconductor wafer to raise a pattern therein; doping the raised pattern of the first semiconductor wafer through the about 500 angstrom thick oxide layer; providing a second semiconductor wafer having an oxide thereover; and, bonding the first semiconductor wafer oxide to the second semiconductor wafer oxide at an elevated temperature.

Abstract: A precision resistor is formed with a controllable resistance to compensate for variations that occur with temperature. An embodiment includes forming a resistive semiconductive element having a width and a length on a substrate, patterning an electrically conductive line across the width of the resistive semiconductive element, but electrically isolated therefrom, and forming a depletion channel in the resistive semiconductive element under the electrically conductive line to control the resistance value of the resistive semiconductive element. The design enables dynamic adjustment of the resistance, thereby improving the reliability of the resistor or allowing for resistance modification during final packaging.

Abstract: The semiconductor device includes a resistor cell that includes a diffused layer resistor, a P-well contact and an N-well contact. The diffused layer resistor is arranged on a semiconductor substrate and is formed by a diffused layer. The P-well contact surrounds an outer rim of the diffused layer resistor and is formed by another diffused layer. The N-well contact is arranged surrounding the outer rim of the P-well contact and is formed by a further diffused layer. Both the P-well and N-well contacts are partitioned into contact portions. Control electrode layer portions are arranged between neighboring contact sections of the P-well contact so the contact sections of the P-well contact and the control electrode layer portions alternate. Control electrode layer portions are arranged between neighboring contact sections of the N-well contact so that the contact sections of the N-well contact and the control electrode layer portions alternate with one another.

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

Abstract: Voltage-controlled semiconductor structures, voltage-controlled resistors, and manufacturing processes are provided. The semiconductor structure comprises a substrate, a first doped well, and a second doped well. The substrate is doped with a first type of ions. The first doped well is with a second type of ions and is formed in the substrate. The second doped well is with the second type of ions and is formed in the substrate. The first type of ions and the second type of ions are complementary. A resistor is formed between the first doped well and the second doped well. A resistivity of the resistor is controlled by a differential voltage. A resistivity of the resistor relates to a first depth of the first doped well, a second depth of the second doped well, and a distance between the first doped well and the second doped well. The resistivity of the resistor is higher than that of a well resistor formed in a single doped well with the second type of ions.

Abstract: A semiconductor device of the invention has a plurality of resistor elements formed on an element isolating oxide film in predetermined regions on a surface of a semiconductor substrate. Active regions are furnished close to the resistor elements. This allows the element isolating oxide film near the resistor elements to be divided into suitable strips, forestalling a concave formation at the center of the element isolating oxide film upon polishing of the film by CMP and thereby enhancing dimensional accuracy of the resistor elements upon fabrication.

Abstract: A process for producing a carbon nanotube resistor that is capable of providing a highly reliable resistor or fuse. The process comprises the step of introducing a carbon nanotube in a volatile solvent to a first concentration and conducting ultrasonic treatment thereof to thereby obtain an initial solution; the dilution step of stepwise diluting the initial solution with a volatile solvent under ultrasonication so as to adjust the same to a second concentration, thereby obtaining a coating solution; and the step of applying the coating solution between a fist electrode and a second electrode, wherein the first concentration is 1(E10?4 g/ml or higher and the second concentration lower than 1(E10?5 g/ml.

Abstract: The present invention provides a semiconductor device including a resistor which achieves reduction of a chip size and variations in resistance value, and a manufacturing method thereof. The semiconductor device includes: a resistor which is linearly formed above the silicon substrate, and made mainly of silicon; contact forming areas each of which (i) is formed in contact with one end of the resistor, and (ii) has a surface made of metal silicide; and contact plugs each of which electrically connects an associated one of the contact forming areas to a metal wire formed on the interlayer insulating film. An in-plane pattern of each of the contact forming areas is bent at least twice in a planar direction with respect to a linear direction of the resistor, so that a part of the contact forming area is formed in parallel with the resistor.

Abstract: A phase change memory device includes a semiconductor substrate active region, a plurality of first conductivity type silicon pillars, and a plurality of second conductivity type silicon patterns. The plurality of first conductivity type silicon pillars is formed on the semiconductor active region such that each first conductivity type silicon pillar is provided for two adjoining cells. The plurality of second conductivity type silicon patterns is formed on the plurality of first conductivity type silicon pillars such that two second conductivity type silicon patterns are formed on opposite sidewalls of each first conductivity type silicon pillars. Two adjoining cells together share only one first conductivity type silicon pillar and each adjoining cell is connected to only one second conductivity type silicon pattern which constitutes a PN diode which serves as a single switching element for each corresponding cell.

Abstract: An integrated circuit structure with a metal-to-metal capacitor and a metallic device such as a resistor, effuse, or local interconnect where the bottom plate of the capacitor and the metallic device are formed with the same material layers. A process for forming a metallic device along with a metal-to-metal capacitor with no additional manufacturing steps.

Abstract: A mechanism for changing the doping profile of semiconductor devices over time using radioisotope dopants is disclosed. This mechanism can be used to activate or deactivate a device based on the change in doping profile over time. The disclosure contains several possible dopants for common semiconductor substrates and discusses several simple devices which could be used to actuate a circuit. The disclosure further discloses a means for determining the optimal doping profile to achieve a transition in bulk electrical properties of a semiconductor at a specific time.

Abstract: Microelectronic structures and devices, and method of fabricating a three-dimensional microelectronic structure is provided, comprising passing a first precursor material for a selected three-dimensional microelectronic structure into a reaction chamber at temperatures sufficient to maintain said precursor material in a predominantly gaseous state; maintaining said reaction chamber under sufficient pressures to enhance formation of a first portion of said three-dimensional microelectronic structure; applying an electric field between an electrode and said microelectronic structure at a desired point under conditions whereat said first portion of a selected three-dimensional microelectronic structure is formed from said first precursor material; positionally adjusting either said formed three-dimensional microelectronic structure or said electrode whereby further controlled growth of said three-dimensional microelectronic structure occurs; passing a second precursor material for a selected three-dimensional mi

Abstract: An integrated circuit memory device may include a semiconductor substrate and a plurality of word-line layers wherein adjacent word-line layers are separated by respective word-line insulating layers. A plurality of active pillars may extend from a surface of the semiconductor substrate through the plurality of word-line layers and insulating layers. Dielectric information storage layers may be provided between the active pillars and the respective word-line layers. Related methods of operation and fabrication are also discussed.

Abstract: Provided is a method which is capable of producing polycrystalline silicon resistors with a high ratio accuracy so that a precision resistor circuit may be designed. A semiconductor device has a structure in which an occupation area of a metal portion covering a low concentration impurity region constituting each of the polycrystalline silicon resistors is adjusted so that ratio accuracy may be further corrected after a resistance is corrected.

Abstract: A method of fabricating a semiconductor-on-insulator device including: providing a first semiconductor wafer having an about 500 angstrom thick oxide layer thereover; etching the first semiconductor wafer to raise a pattern therein; doping the raised pattern of the first semiconductor wafer through the about 500 angstrom thick oxide layer; providing a second semiconductor wafer having an oxide thereover; and, bonding the first semiconductor wafer oxide to the second semiconductor wafer oxide at an elevated temperature.

Abstract: Semiconductor structures with high impedances for use in biasing for applying voltage bias to part of a device. The semiconductor structure comprises a continuous structure having a plurality of regions of a first semiconductor type (n type or p type) material arranged alternately with at least one region of the opposite type. The structure may be formed from polysilicon and may also include a plurality of intrinsic regions arranged between the n and p type regions. The structure forms a composite diode and provides a high impedance.

Abstract: The formation of devices in semiconductor material is provided using an HF/HCL cleaning process. In one embodiment, the method includes forming at least one hard mask overlaying at least one layer of resistive material, forming at least one opening to a working surface of a silicon substrate of the semiconductor device, and cleaning the semiconductor device with a diluted HF/HCL process. The HF/HCL process includes applying a dilute of HF for a select amount of time and applying a dilute of HCL for a specific amount of time. After cleaning with the diluted HF/HCL process, a silicide contact junction is formed in the at least one opening to the working surface of the silicon substrate, and interconnect metal layers are formed.

Abstract: The semiconductor device includes a resistor cell that includes a diffused layer resistor, a P-well contact and an N-well contact. The diffused layer resistor is arranged on a semiconductor substrate and is formed by a diffused layer. The P-well contact surrounds an outer rim of the diffused layer resistor and is formed by another diffused layer. The N-well contact is arranged surrounding the outer rim of the P-well contact and is formed by a further diffused layer. Both the P-well and N-well contacts are partitioned into contact portions. Control electrode layer portions are arranged between neighboring contact sections of the P-well contact so the contact sections of the P-well contact and the control electrode layer portions alternate. Control electrode layer portions are arranged between neighboring contact sections of the N-well contact so that the contact sections of the N-well contact and the control electrode layer portions alternate with one another.

Abstract: A semiconductor device includes a resistance element. The resistance element includes a first and second conductive films, second insulating film, and contact plugs. The first conductive film is formed on a semiconductor substrate with a first insulating film interposed therebetween. The second insulating film is formed on the first conductive film. The second conductive film is formed on the second insulating film. In the first connection portion, the second insulating film is removed. The first connection portion connects the first conductive film and the second conductive film together. The contact plugs are formed on the second conductive film. The contact plugs are arranged such that a region located on the second conductive film and immediately above the connection portion is sandwiched between the contact plugs.

Abstract: A semiconductor structure is disclosed. The semiconductor structure includes a bulk substrate of a first polarity type, a buried insulator layer disposed on the bulk substrate, an active semiconductor layer disposed on top of the buried insulator layer including a shallow trench isolation region and a diffusion region of the first polarity type, a band region of a second polarity type disposed directly beneath the buried insulator layer and forming a conductive path, a well region of the second polarity type disposed in the bulk substrate and in contact with the band region, a deep trench filled with a conductive material of the first polarity type disposed within the well region, and an electrostatic discharge (ESD) protect diode defined by a junction between a lower portion of the deep trench and the well region.

Abstract: An integrated circuit package is described that includes an integrated circuit die, a plurality of lower contact leads, and an insulating substrate positioned over the die and lower contact leads. The insulating substrate includes a plurality of electrically conducting upper routing traces formed on the bottom surface of the substrate. The traces on the bottom surface of the substrate electrically couple each lower contact lead with an associated I/O pad.

Abstract: Provided are a non-volatile memory device which can be extended in a stack structure and thus can be highly integrated, and a method of manufacturing the non-volatile memory device. The non-volatile memory device includes: at least one first electrode, at least one second electrode crossing the at least one first electrode, at least one data storing layer interposed between the at least one first electrode and the second electrode, at a region in which the at least one first electrode crosses the at least one second electrode and at least one metal silicide layer interposed between the at least one first electrode and the at least one second electrode, at the region in which the at least one first electrode crosses the at least one second electrode.

Abstract: A semiconductor device includes a semiconductor substrate including a semiconductor region surrounded with an element isolation region, a first insulating film formed on the semiconductor region, a pair of resistance elements located at the semiconductor region, each resistance element including a first conductive film formed on the first insulating film, a second insulating film formed on the first conductive film and a second conductive film formed on the second insulating film, a pair of first contact plugs formed on one of the resistance elements and arranged along a first direction relative to the semiconductor region, and a pair of second contact plugs formed on the other resistance element and arranged along the first direction. A first width of the resistance element is a second direction which is perpendicular to the first direction is smaller than half of a second width of the semiconductor region in the second direction.

Abstract: To prevent the destruction of a semiconductor element due to negative resistance, and to reduce the dynamic resistance of a static electricity prevention diode, the ratio of the maximum electric field intensity during an avalanche and the average electric field in a strong electric field region, as well as the impurity density gradient in the vicinity of the strong electric field region are optimized. During avalanche breakdown, a depletion layer is formed across the entire high resistivity region, and its average electric field is kept to ½ or more of the maximum electric field intensity. The density gradients (the depths and impurity densities) of a p+ region and of an n+ region that form a p-n junction of the diode are controlled so that the density gradient in the neighborhood of the high resistivity region does not have negative resistance with respect to increase of the avalanche current.

Abstract: An on-chip, ultra-compact, and programmable semiconductor resistor device and device structure and a method of fabrication. Each semiconductor resistor device structure is formed of one or more conductively connected buried trench type resistor elements exhibiting a precise resistor value. At least two semiconductor resistor device structures may be connected in series or in parallel configuration through the intermediary of one or more fuse devices that may be blown to achieve a desired total resistance value.

Abstract: Semiconductor structures and methods of making a vertical diode structure are provided. The vertical diode structure may have associated therewith a diode opening extending through an insulation layer and contacting an active region on a silicon wafer. A titanium silicide layer may be formed over the interior surface of the diode opening and contacting the active region. The diode opening may initially be filled with an amorphous silicon plug that is doped during deposition and subsequently recrystallized to form large grain polysilicon. The silicon plug has a top portion that may be heavily doped with a first type dopant and a bottom portion that may be lightly doped with a second type dopant. The top portion may be bounded by the bottom portion so as not to contact the titanium silicide layer. In one embodiment of the vertical diode structure, a programmable resistor contacts the top portion of the silicon plug and a metal line contacts the programmable resistor.