Abstract: A semiconductor device is disclosed including a semiconductor layer, a first well doped with dopants of a first conductivity type defined in the semiconductor layer, a second well doped with dopants of a second conductivity type different than the first conductivity type defined in the semiconductor layer adjacent the first well to define a PN junction between the first and second wells, and an isolation structure positioned in the second well. The semiconductor device also includes a first source/drain region positioned in the first well, a second source/drain region positioned in the second well adjacent a first side of the isolation structure, a doped region positioned in the second well adjacent a second side of the isolation structure, and a gate structure positioned above the semiconductor layer, wherein the gate structure vertically overlaps a portion of the doped region.

Abstract: A semiconductor device is disclosed including a semiconductor layer, a first well doped with dopants of a first conductivity type defined in the semiconductor layer, a second well doped with dopants of a second conductivity type different than the first conductivity type defined in the semiconductor layer adjacent the first well to define a PN junction between the first and second wells, and an isolation structure positioned in the second well. The semiconductor device also includes a first source/drain region positioned in the first well, a second source/drain region positioned in the second well adjacent a first side of the isolation structure, a doped region positioned in the second well adjacent a second side of the isolation structure, and a gate structure positioned above the semiconductor layer, wherein the gate structure vertically overlaps a portion of the doped region.

Abstract: At least one method, apparatus and system are provided for forming a hybrid oxide layer for providing for a first region of a finFET device to operate at a first voltage and a second region of the finFET to operate at a second voltage. A first set of fins are formed on an I/O device portion, and a second set of fins are formed on a core device portion of a substrate. A first and a second oxide layers are deposited on the first and second set of fins, wherein they merge to form a hybrid oxide layer. The thickness of the second oxide layer is based on a first operating voltage for the I/O device portion. The hybrid layer is removed from the core device portion such that the I/O device portion operates at the first voltage and the core device portion operates at a second voltage.

Abstract: A method for controlling the gate length within a FinFET device to increase power performance and the resulting device are provided. Embodiments include forming a vertical gate to extend over a plurality of fins; depositing a respective oxide layer over each of a plurality of skirt regions formed at respective points of intersection of the vertical gate with the plurality of fins; and oxidizing each oxide layer to form a plurality of oxidized gate skirts.

Abstract: At least one method, apparatus and system are provided for forming a hybrid oxide layer for providing for a first region of a finFET device to operate at a first voltage and a second region of the finFET to operate at a second voltage. A first set of fins are formed on an I/O device portion, and a second set of fins are formed on a core device portion of a substrate. A first and a second oxide layers are deposited on the first and second set of fins, wherein they merge to form a hybrid oxide layer. The thickness of the second oxide layer is based on a first operating voltage for the I/O device portion. The hybrid layer is removed from the core device portion such that the I/O device portion operates at the first voltage and the core device portion operates at a second voltage.

Abstract: A device and method to control the heating of an IC chip in a wafer form for measuring various parameters associated therewith are provided. Embodiments include a device having a silicon layer with an upper surface, and on a plastic carrier; a plurality of devices in the silicon layer and electrically coupled through the upper surface to a test control system; a through silicon via (TSV) extending into the silicon layer; and a parallel heating structure adjacent to the plurality of devices electrically coupled to the test control system.

Abstract: A device and method to control the heating of an IC chip in a wafer form for measuring various parameters associated therewith are provided. Embodiments include a device having a silicon layer with an upper surface, and on a plastic carrier; a plurality of devices in the silicon layer and electrically coupled through the upper surface to a test control system; a through silicon via (TSV) extending into the silicon layer; and a parallel heating structure adjacent to the plurality of devices electrically coupled to the test control system.

Abstract: A methodology for inline characterization and temperature profiling that enables parallel measurement of device characteristics at multiple temperatures and the resulting device are disclosed. Embodiments may include calibrating a first device under test (DUT) with respect to at least one heating structure in a metal layer of an integrated circuit (IC), applying a heater voltage to the at least one heating structure, and measuring at least one characteristic of the first DUT at a first temperature corresponding to the heater voltage.

Abstract: A new MOSFET device is described comprising a metal gate electrode, a gate dielectric and an interfacial layer. The interfacial layer comprises a lanthanum hafnium oxide material for modulating the effective work function of the metal gate. The gate dielectric material in contact with the interfacial layer is different that the interfacial layer material. A method for its manufacture is also provided and its applications.

Abstract: A new MOSFET device is described comprising a metal gate electrode, a gate dielectric and an interfacial layer. The electrostatic potential at an interface between the gate electrode and the gate dielectric of a MOSFET device can be controlled by introducing one or more interfacial layer(s) of a dielectric material, at the monolayer(s) level (i.e., preferably two monolayers), between the gate electrode and the gate dielectric. A method for its manufacture is also provided and its applications.