Abstract: A method and structures are provided for implementing metal via gate node high performance stacked vertical transistors in a back end of line (BEOL) on a semiconductor System on Chip (SoC). The high performance stacked vertical transistors include a pair of stacked vertical field effect transistors (FETs) formed by polycrystalline depositions in a stack between planes of a respective global signal routing wire. A channel length of each of the stacked vertical FETs is delineated by the polycrystalline depositions with sequential source deposition, channel deposition and drain deposition; and a wire via defines the gate node.

Abstract: A semiconductor chip has self aligned (where a gate electrode and associated spacers define the source/drain implant with respect to the gate electrode) Field Effect Transistors (FETs) in a back end of the line (BEOL) portion of the semiconductor chip. The FETs are used to make buffer circuits in the BEOL to improve delay and signal integrity of long signal paths on the semiconductor chip.

Abstract: A semiconductor device has a FinFET with at least two independently controllable FETs on a single fin. The fin may have a body area with a width between two vertical sides, each side has a single FET. The fin also may have a top fin area that is wider than the body area and is electrically independent from the two FETs. The top fin area may be capable of receiving a body contact structure which may be connected to an electrical conductor as to regulate the voltage in the body area of the fin.

Abstract: A plural differential pair may include a first semiconductor fin having first and second drain areas. First and second body areas may be disposed on the fin between the first and second drain areas. A source area may be disposed on the fin between the first and second body areas. The plural differential pair may include a first pair of fin field effect (FinFET) transistors and a second pair of FinFET transistors. The plural differential pair may include first and second top fin areas projecting from respective portions of a top side of the first and second body areas of the fin. The first and second top fin areas may each have a width that is wider than the first and second body areas of the fin.

Abstract: A method and circuit for implementing field effect transistors (FETs) having a gate within a gate utilizing a replacement metal gate process (RMGP), and a design structure on which the subject circuit resides are provided. A field effect transistor utilizing a RMGP includes a sacrificial gate in a generally central metal gate region on a dielectric layer on a substrate, a source and drain formed in the substrate, a pair of dielectric spacers, a first metal gate and a second metal gate replacing the sacrificial gate inside the central metal gate region, and a second gate dielectric layer separating the first metal gate and the second metal gate. A respective electrical contact is formed on opposite sides of the central metal gate region for respectively electrically connecting the first metal gate and the second metal gate to a respective voltage.

Abstract: Methods and structures are provided for implementing independently voltage controlled isolated silicon regions under a buried oxide layer for biasing field effect transistors above the buried oxide layer on Silicon-on-Insulator (SOI) wafers. Using a bonded-wafer technique, a first bulk substrate wafer is bonded with a second wafer providing a buried oxide (BOX) layer under a transistor silicon layer creating an SOI wafer. An independently voltage controlled isolated silicon region is created in the created SOI wafer beneath the BOX layer. The transistor silicon layer is polished to a desired thickness, and normal processing is continued with transistors and desired circuits placed over the isolated silicon region. A contact is formed through the transistor silicon layer and BOX layer to the isolated silicon region for connecting the independently voltage controlled isolated silicon region to a voltage.

Abstract: An apparatus includes a first radiation detector to generate a first signal when a first radiation level is exceeded and a second radiation detector to generate a second signal when a second radiation level is exceeded. The second radiation level is greater than the first radiation level. A first circuit is susceptible to soft errors at the first radiation level and a second circuit is susceptible to soft errors at the second radiation level. A control unit may suspend use of the first circuit and activate use of the second circuit if the first signal is received and the second signal is not received. The first and second circuits may be memory cells or logic circuits.

Abstract: A semiconductor device includes a source extending into a surface of a substrate, a drain extending into the surface of the substrate, and an embedded gate in the substrate extending from the source to the drain.

Abstract: A method and circuit for implementing an embedded dynamic random access memory (eDRAM), and a design structure on which the subject circuit resides are provided. The embedded dynamic random access memory (eDRAM) circuit includes a stacked field effect transistor (FET) and capacitor. The capacitor is fabricated directly on top of the FET to build the eDRAM.

Abstract: A method and structures are provided for implementing vertical transistors utilizing wire vias as gate nodes. The vertical transistors are high performance transistors fabricated up in the stack between the planes of the global signal routing wire, for example, used as vertical signal repeater transistors. An existing via or a supplemental vertical via between wire planes provides both an electrical connection and the gate node of the novel vertical transistor.

Abstract: A method and circuit for implementing an embedded dynamic random access memory (eDRAM), and a design structure on which the subject circuit resides are provided. The embedded dynamic random access memory (eDRAM) circuit includes a stacked field effect transistor (FET) and capacitor. The capacitor is fabricated directly on top of the FET to build the eDRAM.

Abstract: Implementing circuit tuning post design of an integrated circuit utilizing gate phases. Each phase includes a designation of one of a slow phase and a fast phase. During the circuit design phase, each device is given a phase designation based upon expected performance of the device in the circuit. If the device is expected to be in a critical path or has a minimum timing slack, the device is placed on the fast phase. If the device is not in a critical path or has excess timing slack the device is placed on the slow phase.

Abstract: Implementing circuit tuning post design of an integrated circuit utilizing gate phases. Each phase includes a designation of one of a slow phase and a fast phase. During the circuit design phase, each device is given a phase designation based upon expected performance of the device in the circuit. If the device is expected to be in a critical path or has a minimum timing slack, the device is placed on the fast phase. If the device is not in a critical path or has excess timing slack the device is placed on the slow phase.

Abstract: A semiconductor chip has an embedded dynamic random access memory (eDRAM) in an independently voltage controlled silicon region that is a circuit element useful for controlling capacitor values of eDRAM deep trench capacitors and threshold voltages of field effect transistors overlying the independently voltage controlled silicon region. Retention time and performance of the eDRAM is controlled by applying a voltage to the independently voltage controlled silicon region.

Abstract: Vertically stacked Field Effect Transistors (FETs) are created on a vertical structure formed on a semiconductor substrate where a first FET and a second FET are controllable independently. A bipolar junction transistor is connected between and in series with the first FET and the second FET, the bipolar junction transistor may be controllable independently of the first and second FET.

Abstract: A method and an eFuse circuit for implementing with enhanced eFuse blow operation without requiring a separate high current and high voltage supply to blow the eFuse, and a design structure on which the subject circuit resides are provided. The eFuse circuit includes an eFuse connected to a field effect transistor (FET) operatively controlled during a sense mode and a blow mode for sensing and blowing the eFuse. The eFuse circuit is placed over an independently voltage controlled silicon region. During a sense mode, the independently voltage controlled silicon region is grounded providing an increased threshold voltage of the FET. During a blow mode, the independently voltage controlled silicon region is charged to a voltage supply potential. The threshold voltage of the FET is reduced by the charged independently voltage controlled silicon region for providing enhanced FET blow function.

Abstract: A semiconductor device includes a source extending into a surface of a substrate, a drain extending into the surface of the substrate, and an embedded gate in the substrate extending from the source to the drain.

Abstract: A method and circuits for implementing a temporary disable function at indeterminate times of circuitry to be protected in a semiconductor chip, such as in an integrated circuit or a system on a chip (SOC) by modulating threshold voltage shifts of a timing sensitive circuit, and a design structure on which the subject circuit resides are provided. The timing sensitive circuit is designed to be sensitive to threshold-voltage shifts and is placed over an independently voltage controlled silicon region. Upon startup, the independently voltage controlled silicon region is grounded, and then is left floating. Each time a hack attempt or predefined functional oddity is detected, charge is applied onto the independently voltage controlled silicon region. After a defined charge has accumulated, the device threshold voltages in the timing sensitive circuit above the independently voltage controlled silicon region are modulated causing the timing-sensitive circuit to fail.

Abstract: A method and structures are provided for implementing metal via gate node high performance stacked vertical transistors in a back end of line (BEOL) on a semiconductor System on Chip (SoC). The high performance stacked vertical transistors include a pair of stacked vertical field effect transistors (FETs) formed by polycrystalline depositions in a stack between planes of a respective global signal routing wire. A channel length of each of the stacked vertical FETs is delineated by the polycrystalline depositions with sequential source deposition, channel deposition and drain deposition; and a wire via defines the gate node.

Abstract: A method and structures are provided for implementing vertical transistors utilizing wire vias as gate nodes. The vertical transistors are high performance transistors fabricated up in the stack between the planes of the global signal routing wire, for example, used as vertical signal repeater transistors. An existing via or a supplemental vertical via between wire planes provides both an electrical connection and the gate node of the novel vertical transistor.