Abstract: Reconfigurable electronic structures and circuits using programmable, non-volatile memory elements. The programmable, non-volatile memory elements may perform the functions of storage and/or a switch to produce components such as crossbars, multiplexers, look-up tables (LUTs) and other logic circuits used in programmable logic structures (e.g., (FPGAs)). The programmable, non-volatile memory elements comprise one or more structures based on Phase Change Memory, Programmable Metallization, Carbon Nano-Electromechanical (CNT-NEM), or Metal Nano-Electromechanical device technologies.

Abstract: Phase change devices, and particularly multi-terminal phase change devices, include first and second active terminals bridged together by a phase-change material whose conductivity can be modified in accordance with a control signal applied to a control electrode. This structure allows an application in which an electrical connection can be created between the two active terminals, with the control of the connection being effected using a separate terminal or terminals. Accordingly, the resistance of the heater element can be increased independently from the resistance of the path between the two active terminals. This allows the use of smaller heater elements thus requiring less current to create the same amount of Joule heating per unit area. The resistance of the heating element does not impact the total resistance of the phase change device.

Abstract: Phase change devices, and particularly multi-terminal phase change devices, include first and second active terminals bridged together by a phase-change material whose conductivity can be modified in accordance with a control signal applied to a control electrode. This structure allows an application in which an electrical connection can be created between the two active terminals, with the control of the connection being effected using a separate terminal or terminals. Accordingly, the resistance of the heater element can be increased independently from the resistance of the path between the two active terminals. This allows the use of smaller heater elements thus requiring less current to create the same amount of Joule heating per unit area. The resistance of the heating element does not impact the total resistance of the phase change device.

Abstract: Phase change devices, and particularly multi-terminal phase change devices, include first and second active terminals bridged together by a phase-change material whose conductivity can be modified in accordance with a control signal applied to a control electrode. This structure allows an application in which an electrical connection can be created between the two active terminals, with the control of the connection being effected using a separate terminal or terminals. Accordingly, the resistance of the heater element can be increased independently from the resistance of the path between the two active terminals. This allows the use of smaller heater elements thus requiring less current to create the same amount of Joule heating per unit area. The resistance of the heating element does not impact the total resistance of the phase change device.

Abstract: Impedance matching and trimming apparatuses and methods using programmable resistance devices. According to one exemplary embodiment, the impedance matching circuit includes a programmable resistance element, a comparator, a resistor divider having a common node coupled to a first input of the comparator, and an impedance element control circuit coupled between an output of the comparator and the programmable resistance element. The programmable resistance element includes one or more programmable resistance devices (PRDs). Programmed resistances of the programmable resistance element combine with the resistance of an external reference resistor to provide an impedance matched termination. A change in the resistance of the termination impedance causes a change in the output of the comparator.

Abstract: Apparatus and methods for reducing single-event upsets (SEUs) in latch-based circuitry (e.g., static random access memory (SRAM) cells) and other digital circuitry. According to an exemplary embodiment, a latch-based circuit includes a radiation-hardened latch having first and second cross-coupled inverters and first and second programmable resistance devices (PRDs). The first PRD is coupled between the output of the first inverter and the input of the second inverter. The second PRD is coupled between the output of the second inverter and the input of the first inverter. The PRDs may be programmed to low or high-resistance states. When SET to a low-resistance state, the latch of the latch-based circuitry may be accessed to read the current logic state stored by the latch or to write a new logic state into the latch. When RESET to a high-resistance state, the latch is in a radiation-hard state, thereby preventing the latch from generating SEUs.

Abstract: Reconfigurable electronic structures and circuits using programmable, non-volatile memory elements. The programmable, non-volatile memory elements may perform the functions of storage and/or a switch to produce components such as crossbars, multiplexers, look-up tables (LUTs) and other logic circuits used in programmable logic structures (e.g., (FPGAs)). The programmable, non-volatile memory elements comprise one or more structures based on Phase Change Memory, Programmable Metallization, Carbon Nano-Electromechanical (CNT-NEM), or Metal Nano-Electromechanical device technologies.

Abstract: Phase change devices, and particularly multi-terminal phase change devices, include first and second active terminals bridged together by a phase-change material whose conductivity can be modified in accordance with a control signal applied to a control electrode. This structure allows an application in which an electrical connection can be created between the two active terminals, with the control of the connection being effected using a separate terminal or terminals. Accordingly, the resistance of the heater element can be increased independently from the resistance of the path between the two active terminals. This allows the use of smaller heater elements thus requiring less current to create the same amount of Joule heating per unit area. The resistance of the heating element does not impact the total resistance of the phase change device.

Abstract: Phase change devices, and particularly multi-terminal phase change devices, include first and second active terminals bridged together by a phase-change material whose conductivity can be modified in accordance with a control signal applied to a control electrode. This structure allows an application in which an electrical connection can be created between the two active terminals, with the control of the connection being effected using a separate terminal or terminals. Accordingly, the resistance of the heater element can be increased independently from the resistance of the path between the two active terminals. This allows the use of smaller heater elements thus requiring less current to create the same amount of Joule heating per unit area. The resistance of the heating element does not impact the total resistance of the phase change device.

Abstract: A process whereby elimination of metal extrusion through the via-barrier layer into the base of etched via holes is accomplished by controlling the process temperature of the via-barrier deposition to less than 400° C., and preferably to about 380° C. By eliminating the cause of metal extrusions, i.e., excessive thermally induced stresses on the metal confined biaxially by the dielectric via walls, the resulting defect-free vias are independent of the barrier thickness. The method is applicable to different metal stacks, and in turn, yield and reliability of the device is significantly enhanced.

Abstract: A process whereby elimination of metal extrusion through the via-barrier layer into the base of etched via holes is accomplished by controlling the process temperature of the via-barrier deposition to less than 400° C., and preferably to about 380° C. By eliminating the cause of metal extrusions, i.e., excessive thermally induced stresses on the metal confined biaxially by the dielectric via walls, the resulting defect-free vias are independent of the barrier thickness. The method is applicable to different metal stacks, and in turn, yield and reliability of the device is significantly enhanced.

Abstract: A process whereby elimination of metal extrusion through the via-barrier layer into the base of etched via holes is accomplished by controlling the process temperature of the via-barrier deposition to less than 400° C., and preferably to about 380° C. By eliminating the cause of metal extrusions, i.e., excessive thermally induced stresses on the metal confined biaxially by the dielectric via walls, the resulting defect-free vias are independent of the barrier thickness. The method is applicable to different metal stacks, and in turn, yield and reliability of the device is significantly enhanced.