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 fuse structure and method of forming the same is described, wherein the body of the fuse is formed from a crystalline semiconductor body on an insulator, preferably of a silicon-on-insulator wafer, surrounded by a fill-in dielectric. The fill-in dielectric is preferably a material that minimizes stresses on the crystalline body, such as an oxide. The body may be doped, and may also include a silicide layer on the upper surface. This fuse structure may be successfully programmed over a wide range of programming voltages and time.

Abstract: A fuse structure comprises a cavity interposed between a substrate and a fuse material layer. The cavity is not formed at a sidewall of the fuse material layer, or at a surface of the fuse material layer opposite the substrate. A void may be formed interposed between the substrate and the fuse material layer while using a self-aligned etching method, when the fuse material layer comprises lobed ends and a narrower middle region. The void is separated by a pair of sacrificial layer pedestals that support the fuse material layer. The void is encapsulated to form the cavity by using an encapsulating dielectric layer. Alternatively, a block mask may be used when forming the void interposed between the substrate and the fuse material layer.

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: Systems, methods, and design structures whereby operation of and/or access to particular features of an electronic device may be controlled after the device has left the control of the manufacturer are provided. The operation and/or access may be provided based on values stored in non-volatile storage elements, such as electrically programmable fused (eFUSES).

Abstract: An integrated circuit device having at least one fuse capable of being blown in order to provide measurements of fuse current-voltage characteristics is provided. The integrated circuit device also provides at least one pulse generation circuit associated with the fuse and capable of generating a pulse to blow the fuse through one or more DC input signals.

Abstract: An integrated circuit device having at least one fuse capable of being blown in order to provide measurements of fuse current-voltage characteristics is provided. The integrated circuit device also provides at least one pulse generation circuit associated with the fuse and capable of generating a pulse to blow the fuse through one or more DC input signals.

Abstract: Techniques and systems whereby operation of and/or access to particular features of an electronic device may be controlled after the device has left the control of the manufacturer are provided. The operation and/or access may be provided based on values stored in non-volatile storage elements, such as electrically programmable fuses (eFUSES).

Abstract: A reversible fuse structure in an integrated circuit is obtained through the implementation of a fuse cell having a short thin line of phase change materials in contact with via and line structures capable of passing current through the line of phase change material (fuse cell). The current is passed through the fuse cell in order to change the material from a less resistive material to a more resistive material through heating the phase change material in the crystalline state to the melting point then quickly quenching the material into the amorphous state. The reversible programming is achieved by passing a lower current through the fuse cell to convert the high resistivity amorphous material to a lower resistivity crystalline material. Appropriate sense-circuitry is integrated to read the information stored in the fuses, wherein said sense circuitry is used to enable or disable circuitry.

Abstract: An integrated circuit device having at least one fuse capable of being blown in order to provide measurements of fuse current-voltage characteristics is provided. The integrated circuit device also provides at least one pulse generation circuit associated with the fuse and capable of generating a pulse to blow the fuse through one or more DC input signals.

Abstract: Techniques and systems whereby operation of and/or access to particular features of an electronic device may be controlled after the device has left the control of the manufacturer are provided. The operation and/or access may be provided based on values stored in non-volatile storage elements, such as electrically programmable fuses (eFUSES).

Abstract: A secure device for electronic voting employs a write-once vote-recording medium. The medium has an initial writing mode in which data can be written but not read and a subsequent reading mode whereby data can be read but writing is permanently disabled. Once switched from the writing mode to the reading mode, it cannot be switched back. A hardware mechanism provides successful write confirmation The medium can be installed like a cartridge into a vote-recording device. The voting device provides encryption/authorization that combines polling parameters with voter information to produce a “fuse string”. For each vote, a fuse string is written to the array. The poll is “closed” by switching the medium to “read” mode, preventing further modification or tampering. To read out the results of the poll, an auditor enters “password” information to decode/decrypt the recorded information.

Abstract: Techniques and systems whereby operation of and/or access to particular features of an electronic device may be controlled after the device has left the control of the manufacturer are provided. The operation and/or access may be provided based on values stored in non-volatile storage elements, such as electrically programmable fuses (eFUSES).

Abstract: A fuse structure and method of forming the same is described, wherein the body of the fuse is formed from a crystalline semiconductor body on an insulator, preferably of a silicon-on-insulator wafer, surrounded by a fill-in dielectric. The fill-in dielectric is preferably a material that minimizes stresses on the crystalline body, such as an oxide. The body may be doped, and may also include a silicide layer on the upper surface. This fuse structure may be successfully programmed over a wide range of programming voltages and time.

Abstract: The present invention relates to electrical fuses that each comprises at least one thin film transistor. In one embodiment, the electrical fuse of the present invention comprises a hydrogenated thin film transistor with an adjacent heating element. Programming of such an electrical fuse can be effectuated by heating the hydrogenated thin film transistor so as to cause at least partial dehydrogenation. Consequentially, the thin film transistor exhibits detectible physical property change(s), which defines a programmed state. In an alternative embodiment of the present invention, the electrical fuse comprises a thin film transistor that is either hydrogenated or not hydrogenated. Programming of such an alternative electrical fuse can be effectuated by applying a sufficient high back gate voltage to the thin film transistor to cause state changes in the channel-gate interface. In this manner, the thin film transistor also exhibits detectible property change(s) to define a programmed state.

Abstract: A fuse structure and method of forming the same is described, wherein the body of the fuse is formed from a crystalline semiconductor body on an insulator, preferably of a silicon-on-insulator wafer, surrounded by a fill-in dielectric. The fill-in dielectric is preferably a material that minimizes stresses on the crystalline body, such as an oxide. The body may be doped, and may also include a silicide layer on the upper surface. This fuse structure may be successfully programmed over a wide range of programming voltages and time.

Abstract: The present invention provides a dense semiconductor fuse array having common cathodes. The dense semiconductor fuse array of the present invention occupies less area than conventional semiconductor fuse arrays, can comprise integrated diodic components, and can require only one metal wiring layer for making electrical connections to the fuse array.

Abstract: A secure device for electronic voting is employs a write-once vote-recording cartridge, preferably based on an e-fuse array. The cartridge has two distinct modes of operation: write mode and read mode. When in write mode, the array can only be written—it cannot be read. When in read mode, the array can only be read—it cannot be written. The array starts out in write mode. When switched to read mode, it cannot be switched back. A hardware mechanism provides successful write confirmation. The e-fuse array is installed (like a cartridge) into a vote-recording device. The voting device has an encryption/authorization mechanism that combines polling parameters (entered by the polling authority) with user (voter) information (Voter ID confirmation, poll selections, etc.) to produce a “fuse string” to be written into the e-fuse array. Upon completion of each vote, the fuse string from is written to the array, with hardware confirmation of successful writing.

Abstract: The present invention provides electrically-programmable fuse structures having radiation inhibitive properties for preventing non-destructive security breaches by radiation imaging techniques such as X-ray imaging, without adversely effecting fuse programmability, and methods of designing the same.

Abstract: A reversible fuse structure in an integrated circuit is obtained through the implementation of a fuse cell having a short thin line of phase change materials in contact with via and line structures capable of passing current through the line of phase change material (fuse cell). The current is passed through the fuse cell in order to change the material from a less resistive material to a more resistive material through heating the phase change material in the crystalline state to the melting point then quickly quenching the material into the amorphous state. The reversible programming is achieved by passing a lower current through the fuse cell to convert the high resistivity amorphous material to a lower resistivity crystalline material. Appropriate sense-circuitry is integrated to read the information stored in the fuses, wherein said sense circuitry is used to enable or disable circuitry.