Abstract: A semiconductor device includes a first buried gate structure in a peripheral circuit area of a semiconductor substrate, and a second gate structure formed on the semiconductor substrate. A gate insulating layer of a program transistor is thinly formed to be easily ruptured, and a gate insulating layer of a select transistor is thickly formed to improve reliability of the select transistor.

Abstract: The present invention provides a vertical type sensor, including a substrate; a first electrode formed on the substrate; a sensing layer formed on the first electrode layer and reactive to a target substance, wherein the first electrode layer is interposed between the substrate and the sensing layer; and a second electrode layer formed on the sensing layer and having a plurality of openings, wherein the sensing layer is interposed between the first electrode layer and the second electrode layer, and the target substance contacts the sensing layer via the plurality of openings. The vertical type sensor of the present invention provides instant, sensitive and rapid detection.

Abstract: An electronic device can include a nonvolatile memory cell, wherein the nonvolatile memory cell can include an access transistor, a read transistor, and an antifuse component coupled to the access transistor and the read transistor. In an embodiment, the read transistor can include a gate electrode, and the antifuse component can include a first electrode and a second electrode overlying the first electrode. The gate electrode and the first electrode can be parts of the same gate member. In another embodiment, the access transistor can include a gate electrode, and the antifuse component can include a first electrode, an antifuse dielectric layer, and a second electrode. The electronic device can further include a conductive member overlying the antifuse dielectric layer and the gate electrode of the access transistor, wherein the conductive member is configured to electrically float. Processes for making the same are also disclosed.

Abstract: A polycrystalline fuse includes a first layer of polycrystalline material on a substrate and a second layer of a silicide material on the first layer. The first and second layers are shaped to form first and second terminal portions of a first width joined along a length of the fuse by a fuse portion of a second width narrower than the first width. First and second contacts are connected to the first and second terminal portions respectively. The silicide material being discontinuous in a terminal region of the second layer along the length of the fuse.

Abstract: A method of treating a sheet of semiconducting material comprises forming a sinterable first layer over each major surface of a sheet of semiconducting material, forming a second layer over each of the first layers to form a particle-coated semiconductor sheet, placing the particle-coated sheet between end members, heating the particle-coated sheet to a temperature effective to at least partially sinter the first layer and at least partially melt the semiconducting material, and cooling the particle-coated sheet to solidify the semiconducting material and form a treated sheet of semiconducting material.

Abstract: A semiconductor device which does not reduce writing property of a memory element and a method for manufacturing the same are proposed even in the case of forming a silicon film at a step portion formed by a surface of a substrate and a wiring formed over the substrate. The semiconductor device includes a plurality of the memory elements comprising a first electrode formed over a substrate having an insulating surface, sidewall insulating layer formed on side surface of the first electrode, a silicon film formed to cover the first electrode and the sidewall insulating layer, and a second electrode formed over the silicon film, and at least one of the first electrode and the second electrode is formed with a material being capable of being alloyed with the silicon film.

Abstract: An integrated circuit structure is provided. The integrated circuit structure includes a semiconductor substrate; a dielectric layer over the semiconductor substrate; a metal fuse in the dielectric layer; a dummy pattern adjacent the metal fuse; and a metal line in the dielectric layer, wherein a thickness of the metal fuse is substantially less than a thickness of the metal line.

Abstract: An integrated circuit including vertically oriented diode structures between conductors and methods of fabricating the same are provided. Two-terminal devices such as passive element memory cells can include a diode steering element in series with an antifuse and/or other state change element. The devices are formed using pillar structures at the intersections of upper and lower sets of conductors. The height of the pillar structures are reduced by forming part of the diode for each pillar in a rail stack with one of the conductors. A diode in one embodiment can include a first diode component of a first conductivity type and a second diode component of a second conductivity type. A portion of one of the diode components is divided into first and second portions with one on the portions being formed in the rail stack where it is shared with other diodes formed using pillars at the rail stack.

Abstract: An electronic device can include a nonvolatile memory cell, wherein the nonvolatile memory cell can include a substrate, an access transistor, a read transistor, and an antifuse component. Each of the access and read transistors can include source/drain regions at least partly within the substrate, a gate dielectric layer overlying the substrate, and a gate electrode overlying the gate dielectric layer. An antifuse component can include a first electrode lying at least partly within the substrate, an antifuse dielectric layer overlying the substrate, and a second electrode overlying the antifuse dielectric layer. The second electrode of the antifuse component can be coupled to one of the source/drain regions of the access transistor and to the gate electrode of the read transistor. In an embodiment, the antifuse component can be in the form of a transistor structure. The electronic device can be formed using a single polysilicon process.

Abstract: A memory device is provided, which includes a memory element including a first electrode, a second electrode, and a silicon layer disposed between the first electrode and the second electrode. The memory element is capable of being in a first state, a second state, and a third state. A first data is written to the memory element being in the first state so that a potential of the first electrode is higher than a potential of the second electrode, whereby the memory element being in the second state is obtained. A second data is written to the memory element being in the first state so that a potential of the second electrode is higher than a potential of the first electrode, whereby the memory element being in the third state is obtained.

Abstract: An anti-fuse device includes a gate electrode on a semiconductor substrate, a gate insulating layer between the semiconductor substrate and the gate electrode, junction regions in the semiconductor substrate adjacent the gate electrode, and at least one anti-breakdown material layer between the junction regions, the gate insulating layer being between the gate electrode and the anti-breakdown material layer.

Abstract: A memory device in a 3-D read and write memory includes a resistance-changing layer, and a local contact resistance in series with, and local to, the resistance-changing layer. The local contact resistance is established by a junction between a semiconductor layer and a metal layer. Further, the local contact resistance has a specified level of resistance according to a doping concentration of the semiconductor and a barrier height of the junction. A method for fabricating such a memory device is also presented.

Abstract: An electric energy generator may include a semiconductor layer and a plurality of nanowires having piezoelectric characteristics. The electric energy generator may convert optical energy into electric energy if external light is applied and may generate piezoelectric energy if external pressure (e.g., sound or vibration) is applied.

Abstract: A method of arranging pads in a semiconductor memory device, the semiconductor memory device using the method, and a processing system having mounted therein the semiconductor memory device. The method includes classifying pads provided in a memory chip of the semiconductor memory device into monitoring pads configured for a memory chip test on a wafer, a package pads configured for wire connection in a package, and common pads configured for both the memory chip test on the wafer and wire connection in the package and arranging the monitoring pads and the package pads separately in columns on the memory chip.

Abstract: It is an object to provide an epitaxial silicon wafer that is provided with an excellent gettering ability in which a polysilicon layer is formed on the rear face side of a silicon crystal substrate into which phosphorus (P) and germanium (Ge) have been doped. A silicon epitaxial layer is grown by a CVD method on the surface of a silicon crystal substrate into which phosphorus and germanium have been doped at a high concentration. After that, a PBS forming step for growing a polysilicon layer is executed on the rear face side of a silicon crystal substrate. By the above steps, the number of LPDs (caused by an SF) that occur on the surface of the epitaxial silicon wafer due to the SF can be greatly reduced.

Abstract: The present invention relates to a semiconductor device including a circuit composed of thin film transistors having a novel GOLD (Gate-Overlapped LDD (Lightly Doped Drain)) structure. The thin film transistor comprises a first gate electrode and a second electrode being in contact with the first gate electrode and a gate insulating film. Further, the LDD is formed by using the first gate electrode as a mask, and source and drain regions are formed by using the second gate electrode as the mask. Then, the LDD overlapping with the second gate electrode is formed. This structure provides the thin film transistor with high reliability.

Abstract: A device is provided that includes a vertically oriented p-i-n diode that includes semiconductor material, a silicide, germanide, or silicide-germanide layer disposed adjacent the vertically oriented p-i-n diode, and a dielectric material arranged electrically in series with the vertically oriented p-i-n diode. The dielectric material is disposed between a first conductive layer and a second conductive layer, and is selected from the group consisting of HfO2, Al2O3, ZrO2, TiO2, La2O3, Ta2O5, RuO2, ZrSiOx, AlSiOx, HfSiOx, HfAlOx, HfSiON, ZrSiAlOx, HfSiAlOx, HfSiAlON, and ZrSiAlON. Numerous other aspects are provided.

Abstract: An anti-fuse element that includes an insulation layer; a pair of electrode layers formed on upper and lower surfaces of the insulation layer; and an extraction electrode contacting a section of the electrode layers forming electrostatic capacitance with the insulation layer. The anti-fuse element is configured to create a structural change section that includes a short circuit section short-circuited such that the pair of electrode layers are fused mutually to engulf the insulation layer, and a dissipation section with the electrode layers and insulation layer dissipated by the engulfing of the insulation layer, when a voltage not less than the breakdown voltage of the insulation layer is applied. The maximum diameter of a section of the extraction electrode in contact with the electrode layer is larger than the maximum diameter of the structural change section.

Abstract: Disclosed herein is a metal e-fuse device that employs an intermetallic compound programming mechanism and various methods of making such an e-fuse device. In one example, a device disclosed herein includes a first metal line, a second metal line and a fuse element that is positioned between and conductively coupled to each of the first and second metal lines, wherein the fuse element is adapted to be blown by passing a programming current therethrough, and wherein the fuse element is comprised of a material that is different from a material of construction of at least one of the first and second metal lines.

Abstract: Silicon nitride antifuses can be advantageously used in memory arrays employing diode-antifuse cells. Silicon nitride antifuses can be ruptured faster and at a lower breakdown field than antifuses formed of other materials, such as silicon dioxide. Examples are given of monolithic three dimensional memory arrays using silicon nitride antifuses with memory cells disposed in rail-stacks and pillars, and including PN and Schottky diodes. Pairing a silicon nitride antifuse with a low-density, high-resistivity conductor gives even better device performance.

Abstract: An antifuse has first and second semiconductor regions having one conductivity type and a third semiconductor region therebetween having an opposite conductivity type. A conductive region contacting the first region has a long dimension in a second direction transverse to the direction of a long dimension of a gate. An antifuse anode is spaced apart from the first region in the second direction and a contact is connected with the second region. Applying a programming voltage between the anode and the contact with gate bias sufficient to fully turn on field effect transistor operation of the antifuse heats the first region to drive a dopant outwardly, causing an edge of the first region to move closer to an edge of the second region and reduce electrical resistance between the first and second regions by an one or more orders of magnitude.

Abstract: Techniques for providing non-volatile antifuse memory elements and other antifuse links are disclosed herein. In sonic embodiments, the antifuse memory elements are configured with non-planar topology such as FinFET topology. In some such embodiments, the fin topology can be manipulated and used to effectively promote lower breakdown voltage transistors, by creating enhanced-emission sites which are suitable for use in lower voltage non-volatile antifuse memory elements. In one example embodiment, a semiconductor antifuse device is provided that includes a non-planar diffusion area having a fin configured with a tapered portion, a dielectric isolation layer on the fin including the tapered portion, and a gate material on the dielectric isolation layer. The tapered portion of the fin may be formed, for instance, by oxidation, etching, and/or ablation, and in some cases includes a base region and a thinned region, and the thinned region is at least 50% thinner than the base region.

Abstract: An antifuse can include an insulated gate field effect transistor (“IGFET”) having an active semiconductor region including a body and first regions, i.e., at least one source region and at least one drain region separated from one another by the body. A gate may overlie the body and a body contact is electrically connected with the body. The first regions have opposite conductivity (i.e., n-type or p-type) from the body. The IGFET can be configured such that a programming current through at least one of the first regions and the body contact causes heating sufficient to drive dopant diffusion from the at least one first region into the body and cause an edge of the at least one first region to move closer to an adjacent edge of at least one other of the first regions. In such way, the programming current can permanently reduce electrical resistance by one or more orders of magnitude between the at least one first region and the at least one other first region.

Abstract: An electronic device can include a nonvolatile memory cell, wherein the nonvolatile memory cell can include an access transistor, a read transistor, and an antifuse component coupled to the access transistor and the read transistor. In an embodiment, the read transistor can include a gate electrode, and the antifuse component can include a first electrode and a second electrode overlying the first electrode. The gate electrode and the first electrode can be parts of the same gate member. In another embodiment, the access transistor can include a gate electrode, and the antifuse component can include a first electrode, an antifuse dielectric layer, and a second electrode. The electronic device can further include a conductive member overlying the antifuse dielectric layer and the gate electrode of the access transistor, wherein the conductive member is configured to electrically float. Processes for making the same are also disclosed.

Abstract: An object of one embodiment of the present invention is to provide an antifuse which has low writing voltage. The antifuse is used for a memory element for a read only memory device. The antifuse includes a first conductive layer, an insulating layer, a semiconductor layer, and a second conductive layer. The insulating layer included in the antifuse is a silicon oxynitride layer formed by adding ammonia to a source gas. When hydrogen is contained in the layer at greater than or equal to 1.2×1021 atoms/cm3 and less than or equal to 3.4×1021 atoms/cm3 or nitrogen is contained in the layer at greater than or equal to 3.2×1020 atoms/cm3 and less than or equal to 2.2×1021 atoms/cm3, writing can be performed at low voltage.

Abstract: An AND-type anti-fuse memory cell, and a memory array consisting of AND-type anti-fuse memory cells. Chains of AND type anti-fuse cells are connected in series with each other, and with a bitline contact, in order to minimize the area occupied by the memory array. Each AND type anti-fuse cell includes an access transistor serially connectable to the bitline or the access transistors of other AND type anti-fuse cells, and an anti-fuse device. The channel region of the access transistor is connected to the channel region of the anti-fuse device, and both channel regions are covered by the same wordline. The wordline is driven to a programming voltage level for programming the anti-fuse device, or to a read voltage level for reading the anti-fuse device.

Abstract: According to one exemplary embodiment, a programmable poly fuse includes a P type resistive poly segment forming a P-N junction with an adjacent N type resistive poly segment. The programmable poly fuse further includes a P side silicided poly line contiguous with the P type resistive poly segment and coupled to a P side terminal of the poly fuse. The programmable poly fuse further includes an N side silicided poly line contiguous with the N type resistive poly segment and coupled to an N side terminal of the poly fuse. During a normal operating mode, a voltage less than or equal to approximately 2.5 volts is applied to the N side terminal of the programmable poly fuse. A voltage higher than approximately 3.5 volts is required at the N side terminal of the poly fuse to break down the P-N junction.

Abstract: An antifuse structure and methods of forming contacts within the antifuse structure. The antifuse structure includes a substrate having an overlying metal layer, a dielectric layer formed on an upper surface of the metal layer, and a contact formed of contact material within a contact via etched through the dielectric layer into the metal layer. The contact via includes a metal material at a bottom surface of the contact via and an untreated or partially treated metal precursor on top of the metal material.

Abstract: An antifuse structure and methods of forming contacts within the antifuse structure. The antifuse structure includes a substrate having an overlying metal layer, a dielectric layer formed on an upper surface of the metal layer, and a contact formed of contact material within a contact via etched through the dielectric layer into the metal layer. The contact via includes a metal material at a bottom surface of the contact via and an untreated or partially treated metal precursor on top of the metal material.

Abstract: An antifuse is provided having a unitary monocrystalline semiconductor body including first and second semiconductor regions each having the same first conductivity type, and a third semiconductor region between the first and second semiconductor regions which has a second conductivity type opposite from the first conductivity type. An anode and a cathode can be electrically connected with the first semiconductor region. A conductive region including a metal, a conductive compound of a metal or an alloy of a metal can contact the first semiconductor region and extend between the cathode and the anode. The antifuse can further include a contact electrically connected with the second semiconductor region.

Abstract: An anti-fuse apparatus includes a substrate of a first conductivity type and a well region of a second conductivity type formed in the substrate. A junction between the well region and the substrate is characterized by a breakdown voltage higher than a predetermined voltage. The apparatus includes a contact region of the second conductivity type within the well region. The apparatus also includes a channel region and a drain region within the substrate. A gate dielectric layer overlies the channel region and the contact region. A first polysilicon gate, the drain region, and the well region are associated with an MOS transistor. The apparatus also includes a second polysilicon gate overlying the gate dielectric layer which overlies the contact region. The contact region is configured to receive a first supply voltage and the second polysilicon gate is configured to receive a second supply voltage.

Abstract: A vertically oriented p-i-n diode is provided that includes semiconductor material crystallized adjacent a silicide, germanide, or silicide-germanide layer, and a dielectric material arranged electrically in series with the diode. The dielectric material has a dielectric constant greater than 8, and is adjacent a first metallic layer and a second metallic layer. Numerous other aspects are provided.

Abstract: After planarization of a gate level dielectric layer, a dummy structure is removed to form a recess. A first conductive material layer and an amorphous metal oxide are deposited into the recess area. A second conduct material layer fills the recess. After planarization, an electrical antifuse is formed within the filled recess area, which includes a first conductive material portion, an amorphous metal oxide portion, and a second conductive material portion. To program the electrical antifuse, current is passed between the two terminals in the pair of the conductive contacts to transform the amorphous metal oxide portion into a crystallized metal oxide portion, which has a lower resistance. A sensing circuit determines whether the metal oxide portion is in an amorphous state (high resistance state) or in a crystalline state (low resistance state).

Abstract: Disclosed are embodiments of a circuit and method for electroplating a feature (e.g., a BEOL anti-fuse device) onto a wafer. The embodiments eliminate the use of a seed layer and, thereby, minimize subsequent processing steps (e.g., etching or chemical mechanical polishing (CMP)). Specifically, the embodiments allow for selective electroplating metal or alloy materials onto an exposed portion of a metal layer in a trench on the front side of a substrate. This is accomplished by providing a unique wafer structure that allows a current path to be established from a power supply through a back side contact and in-substrate electrical connector to the metal layer. During electrodeposition, current flow through the current path can be selectively controlled. Additionally, if the electroplated feature is an anti-fuse device, current flow through this current path can also be selectively controlled in order to program the anti-fuse device.

Abstract: After planarization of a gate level dielectric layer, a dummy structure is removed to form a recess. A first conductive material layer and an amorphous metal oxide are deposited into the recess area. A second conduct material layer fills the recess. After planarization, an electrical antifuse is formed within the filled recess area, which includes a first conductive material portion, an amorphous metal oxide portion, and a second conductive material portion. To program the electrical antifuse, current is passed between the two terminals in the pair of the conductive contacts to transform the amorphous metal oxide portion into a crystallized metal oxide portion, which has a lower resistance. A sensing circuit determines whether the metal oxide portion is in an amorphous state (high resistance state) or in a crystalline state (low resistance state).

Abstract: Structure and method for providing a programmable anti-fuse in a FET structure. A method of forming the programmable anti-fuse includes: providing a p? substrate with an n+ gate stack; implanting an n+ source region and an n+ drain region in the p? substrate; forming a resist mask over the n+ drain region, while leaving the n+ source region exposed; etching the n+ source region to form a recess in the n+ source region; and growing a p+ epitaxial silicon germanium layer in the recess in the n+ source region to form a pn junction that acts as a programmable diode or anti-fuse.

Abstract: A laser activated phase change device for use in an integrated circuit comprises a chalcogenide fuse configured to connect a first patterned metal line and a second patterned metal line and positioned between an inter layer dielectric and an over fuse dielectric. The fuse interconnects active semiconductor elements manufactured on a substrate. A method for activating the laser activated phase change device includes selecting a laser condition of a laser based on characteristics of the fuse and programming a phase-change of the fuse with the laser by direct photon absorption until a threshold transition temperature is met.

Abstract: An element isolation region exists at a side opposite to a diffusion layer region as seen from a channel region, without another electrode to which the same potential as one applied to the diffusion layer region is applied interposed between the channel region and the element isolation region. The electric field applied to the gate insulating film is not uniform and the magnitude of the electric field is increased when approaching closer to the diffusion layer region. Therefore, breakdown is likely to occur at parts closer to the diffusion layer region.

Abstract: An integrated circuit including vertically oriented diode structures between conductors and methods of fabricating the same are provided. Two-terminal devices such as passive element memory cells can include a diode steering element in series with an antifuse and/or other state change element. The devices are formed using pillar structures at the intersections of upper and lower sets of conductors. The height of the pillar structures are reduced by forming part of the diode for each pillar in a rail stack with one of the conductors. A diode in one embodiment can include a first diode component of a first conductivity type and a second diode component of a second conductivity type. A portion of one of the diode components is divided into first and second portions with one on the portions being formed in the rail stack where it is shared with other diodes formed using pillars at the rail stack.

Abstract: The invention relates generally to preparation of a substrate for use in a photovoltaic device by application of a filling material and subsequent planarization of the top surface; optionally, a barrier layer is added.

Abstract: An antifuse structure and methods of forming contacts within the antifuse structure. The antifuse structure includes a substrate having an overlying metal layer, a dielectric layer formed on an upper surface of the metal layer, and a contact formed of contact material within a contact via etched through the dielectric layer into the metal layer. The contact via includes a metal material at a bottom surface of the contact via and an untreated or partially treated metal precursor on top of the metal material.

Abstract: One or more diffusion barriers are formed around one or more conductors in a three dimensional or 3D memory cell. The diffusion barriers allow the conductors to comprise very low resistivity materials, such as copper, that may otherwise out diffuse into surrounding areas, particularly at elevated processing temperatures. Utilizing lower resistivity materials allows device dimension to be reduced by mitigating increases in resistance that occur when the size of the conductors is reduced. As such, more cells can be produced over a given area, thus increasing the density and storage capacity of a resulting memory array.

Abstract: A polycrystalline fuse includes a first layer of polycrystalline material on a substrate and a second layer of a silicide material on the first layer. The first and second layers are shaped to form first and second terminal portions of a first width joined along a length of the fuse by a fuse portion of a second width narrower than the first width. First and second contacts are connected to the first and second terminal portions respectively. The silicide material being discontinuous in a terminal region of the second layer along the length of the fuse.

Abstract: A semiconductor material structure includes at least one region capable of generating electrons and holes each having an associated mean kinetic energy during operation. A material layer in proximity to the region provides an associated potential energy larger than the mean kinetic energy associated with the generated electrons and the mean kinetic energy associated with the holes.

Abstract: A recessed dielectric antifuse device includes a substrate and laterally spaced source and drain regions formed in the substrate. A recess is formed between the source and drain regions. A gate and gate oxide are formed in the recess and lightly doped source and drain extension regions contiguous with the laterally spaced source and drain regions are optionally formed adjacent the recess. Programming of the recessed dielectric antifuse is performed by application of power to the gate and at least one of the source region and the drain region to breakdown the dielectric, which minimizes resistance between the gate and the channel.

Abstract: An RFID transponder comprises an electronic assembly and an antenna assembly. The electronic assembly is a multi-layer film body having one or more electrically conducting functional layers and one or more electrically semiconducting functional layers. The antenna assembly has one or more electrically conducting functional layers, of which one is an antenna coil. In a first region and a second region of the body a respective one of the one or more electrically conducting functional layers forms respective first and second capacitor plates. In addition, in the first region and the second region of the body a respective one of the one or more electrically conducting functional layers of the antenna assembly is formed as a third and a fourth capacitor plate so that the electronic assembly and the antenna assembly are electrically coupled by capacitors formed respectively by the first and third and by the second and fourth capacitor plates.

Abstract: An antifuse (40, 80, 90?) comprises, first (22?, 24?) and second (26?) conductive regions having spaced-apart curved portions (55, 56), with a first dielectric region (44) therebetween, forming in combination with the curved portions (55, 56) a curved breakdown region (47) adapted to switch from a substantially non-conductive initial state to a substantially conductive final state in response to a predetermined programming voltage. A sense voltage less than the programming voltage is used to determine the state of the antifuse as either OFF (high impedance) or ON (low impedance). A shallow trench isolation (STI) region (42) is desirably provided adjacent the breakdown region (47) to inhibit heat loss from the breakdown region (47) during programming. Lower programming voltages and currents are observed compared to antifuses (30) using substantially planar dielectric regions (32).

Abstract: A method forms an anti-fuse structure comprises a plurality of parallel conductive fins positioned on a substrate, each of the fins has a first end and a second end. A second electrical conductor is electrically connected to the second end of the fins. An insulator covers the first end of the fins and a first electrical conductor is positioned on the insulator. The first electrical conductor is electrically insulated from the first end of the fins by the insulator. The insulator is formed to a thickness sufficient to break down on the application of a predetermined voltage between the second electrical conductor and the first electrical conductor and thereby form an uninterrupted electrical connection between the second electrical conductor and the first electrical conductor through the fins.

Abstract: An anti-fuse memory cell having a variable thickness gate oxide. The variable thickness gate oxide has a thick gate oxide portion and a thin gate oxide portion, where the thing gate oxide portion has at least one dimension less than a minimum feature size of a process technology. The thin gate oxide can be rectangular in shape or triangular in shape. The anti-fuse transistor can be used in a two-transistor memory cell having an access transistor with a gate oxide substantially identical in thickness to the thick gate oxide of the variable thickness gate oxide of the anti-fuse transistor.

Abstract: A method is described for forming a nonvolatile one-time-programmable memory cell having reduced programming voltage. A contiguous p-i-n diode is paired with a dielectric rupture antifuse formed of a high-dielectric-constant material, having a dielectric constant greater than about 8. In preferred embodiments, the high-dielectric-constant material is formed by atomic layer deposition. The diode is preferably formed of deposited low-defect semiconductor material, crystallized in contact with a silicide. A monolithic three dimensional memory array of such cells can be formed in stacked memory levels above the wafer substrate.