Abstract: An electromigration-programmable semiconductor device may be programmed to increase the resistance or to decrease the resistance by selecting the amount of current passed through the electromigration-programmable semiconductor device. The electromigration-programmable semiconductor device comprises an anode, a cathode, and a link, each having a semiconductor portion and a metal semiconductor alloy portion. The metal semiconductor alloy portion of the link comprises two disjoined sub-portions with a gap therebetween. A low programming current fills the gap by electromigrating a small amount of metal semiconductor alloy from the cathode, A high programming current forms a large metal-semiconductor-alloy-deleted area in the cathode to increase the resistance. A tri-state programming is achieved by selecting the programming current level.

Abstract: An antifuse structure includes a sense pad contact region that is separate from an anode contact region and a cathode contact region. By including the sense pad contact region that is separate from the anode contact region and the cathode contact region, a programming current flow when programming the antifuse structure may travel a different pathway than a sense current flow when sensing the antifuse structure. In particular a sense current flow may avoid a depletion region created within the cathode contact region when programming the antifuse structure.

Abstract: A fuse structure, a method for fabricating the fuse structure and a method for programming a fuse within the fuse structure each use a fuse material layer that is used as a fuse, and located upon a monocrystalline semiconductor material layer in turn located over a substrate. At least part of the monocrystalline semiconductor material layer is separated from the substrate by a gap. Use of the monocrystalline semiconductor material layer, as well as the gap, provides for enhanced uniformity and reproducibility when programming the fuse.

Abstract: An integrated eFUSE device is formed by forming a silicon “floating beam” on air, whereupon the fusible portion of the eFUSE device resides. This beam extends between two larger, supporting terminal structures. “Undercutting” techniques are employed whereby a structure is formed atop a buried layer, and that buried layer is removed by selective etching. Whereby a “floating” silicide eFUSE conductor is formed on a silicon beam structure. In its initial state, the eFUSE silicide is highly conductive, exhibiting low electrical resistance (the “unblown state of the eFUSE). When a sufficiently large current is passed through the eFUSE conductor, localized heating occurs. This heating causes electromigration of the silicide into the silicon beam (and into surrounding silicon, thereby diffusing the silicide and greatly increasing its electrical resistance. When the current source is removed, the silicide remains permanently in this diffused state, the “blown” state of the eFUSE.

Abstract: A programmable phase change material (PCM) structure includes a heater element formed at a BEOL level of a semiconductor device, the BEOL level including a low-K dielectric material therein; a first via in electrical contact with a first end of the heater element and a second via in electrical contact with a second end of the heater element, thereby defining a programming current path which passes through the first via, the heater element, and the second via; a PCM element disposed above the heater element, the PCM element configured to be programmed between a lower resistance crystalline state and a higher resistance amorphous state through the use of programming currents through the heater element; and a third via in electrical contact with the PCM element, thereby defining a sense current path which passes through the third via, the PCM element, the heater element, and the second via.

Abstract: A programmable phase change material (PCM) structure includes a heater element formed at a transistor gate level of a semiconductor device, the heater element further including a pair of electrodes connected by a thin wire structure with respect to the electrodes, the heater element configured to receive programming current passed therethrough, a layer of phase change material disposed on top of a portion of the thin wire structure, and sensing circuitry configured to sense the resistance of the phase change material.

Abstract: An electrical fuse programming circuit and a method for programming an electrical fuse within the electrical fuse programming circuit use a programming circuit bus to which are electrically connected in parallel the electrical fuse and a bypass resistor. A current within the programming circuit bus is made to flow through the bypass resistor for a period of time sufficient to stabilize the current, and then sequentially and instantaneously switched to program the electrical fuse.

Abstract: The present invention provides a circuit for determining the optimal gate voltage for programming transistors. The determination of the optimal voltage compensates for the variations in the programming current due to process variations in manufacturing or due to ambient conditions. By applying the optimal gate voltage thus determined to the programming transistors of electrical fuses, the optimal level of current is passed through the electrical fuses to enable high yielding and reliable electrical fuse programming.

Abstract: The present invention provides structures for antifuses that utilize electromigration for programming. By providing a portion of antifuse link with high resistance without conducting material and then by inducing electromigration of the conducting material into the antifuse link, the resistance of the antifuse structure is changed. By providing a terminal on the antifuse link, the change in the electrical properties of the antifuse link is detected and sensed. Also disclosed are an integrated antifuse with a built-in sensing device and a two dimensional array of integrated antifuses that can share programming transistors and sensing circuitry.

Abstract: An antifuse having a link including a region of unsilicided semiconductor material may be programmed at reduced voltage and current and with reduced generation of heat by electromigration of metal or silicide from a cathode into the region of unsilicided semiconductor material to form an alloy having reduced bulk resistance. The cathode and anode are preferably shaped to control regions from which and to which material is electrically migrated. After programming, additional electromigration of material can return the antifuse to a high resistance state. The process by which the antifuse is fabricated is completely compatible with fabrication of field effect transistors and the antifuse may be advantageously formed on isolation structures.

Abstract: The present invention provides an electrical fuse structure for achieving a post-programming resistance distribution with higher resistance values and to enhance the reliability of electrical fuse programming. A partly doped electrical fuse structure with undoped semiconductor material in the cathode combined with P-doped semiconductor material in the fuselink and anode is disclosed and the data supporting the superior performance of the disclosed electrical fuse is shown.

Abstract: A programmable phase change material (PCM) structure includes a heater element formed at a transistor gate level of a semiconductor device, the heater element further including a pair of electrodes connected by a thin wire structure with respect to the electrodes, the heater element configured to receive programming current passed therethrough, a layer of phase change material disposed on top of a portion of the thin wire structure, and sensing circuitry configured to sense the resistance of the phase change material.

Abstract: A programmable phase change material (PCM) structure includes a heater element formed at a transistor gate level of a semiconductor device, the heater element further including a pair of electrodes connected by a thin wire structure with respect to the electrodes, the heater element configured to receive programming current passed therethrough, a layer of phase change material disposed on top of a portion of the thin wire structure, and sensing circuitry configured to sense the resistance of the phase change material.

Abstract: The embodiments of the invention generally relate to fuse and anti-fuse structures and include a copper conductor positioned within a substrate and a metal cap on the first conductor. A low-k dielectric is on the substrate and the metal cap. A tantalum nitride resistor is on the dielectric, and the resistor is positioned above the metal cap such that an antifuse element region of the dielectric is positioned between the resistor and the metal cap. The antifuse element region of the dielectric is adapted to change resistance values by application of a voltage difference between the resistor and the copper conductor/metal cap. The antifuse element region has a first higher resistance (more closely matching an insulator) before application of the voltage and a second lower resistance (more closely matching a conductor) after application of such voltage.

Abstract: A programmable structure such as a write once read many (WORM) or one time programmable read only memories (OTPROM) is disclosed herein. The structure includes a first conductor (such as copper) positioned within a substrate and a metal cap on the first conductor. A low-k dielectric is on the substrate and the metal cap. A tantalum nitride resistor is on the dielectric, and the resistor is positioned above the metal cap such that a programmable region of the dielectric is positioned between the resistor and the metal cap. The first conductor (including the metal cap), the programmable region of the dielectric, and the resistor form a metal-insulator-metal capacitor. Further, the programmable region of the dielectric is adapted to be permanently changed from heat produced by the resistor when a voltage difference is applied to the first and second ends of the resistor, respectively, through the first and second contacts.

Abstract: The present invention provides structures for an integrated antifuse that incorporates an integrated sensing transistor with an integrated heater. Two terminals connected to the upper plate allow the heating of the upper plate, accelerating the breakdown of the antifuse dielectric at a lower bias voltage. Part of the upper plate also serves as the gate of the integrated sensing transistor. The antifuse dielectric serves as the gate dielectric of the integrated transistor. The lower plate comprises a channel, a drain, and a source of a transistor. While intact, the integrated sensing transistor allows a passage of transistor current through the drain. When programmed, the antifuse dielectric, which is the gate of the integrated transistor, is subjected to a gate breakdown, shorting the gate to the channel and resulting in a decreased drain current. The integrated antifuse structure can also be wired in an array to provide a compact OTP memory array.

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: 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 method for programming an electronically programmable semiconductor fuse applies a programming current to a fuse link as a series of multiple pulses. The fuse link has a nominal maximum programming current and corresponding combinations of a programming voltage and a gate voltage associated with the nominal maximum programming current. A first programming current pulse is generated to provide a programming current less than the maximum programming current. The first programming current pulse causes electromigration to increase the resistance of the fuse link. A subsequent programming current pulse is applied using a combination of gate voltage and programming voltages which if applied to the fuse link absent any electromigration would result in a programming current greater than the nominal maximum programming current. However, the resistance created by the first programming pulse reduces the programming current of the subsequent programming pulse to a level below the maximum programming current.

Abstract: A chemical mechanical polishing (CMP) apparatus includes a workpiece carrier configured for retaining a workpiece thereupon, a polishing platen configured for retaining a polishing pad thereupon, and an electromagnetic coil surrounding a periphery of the workpiece carrier. The electromagnetic coil is configured to provide a magnetic field of alternating polarity to cause the rotation of ferromagnetic slurry particles disposed on the workpiece to facilitate polishing of the workpiece.