Abstract: A method of forming a semiconductor device that includes forming a fin structure from a bulk semiconductor substrate and forming an isolation region contacting a lower portion of a sidewall of the fin structure, wherein an upper portion of the sidewall of the fin structure is exposed. A sacrificial spacer is formed on the upper portion of the sidewall of the fin structure. The isolation regions are recessed to provide an exposed section of the sidewall of the fin structure. A doped semiconductor material is formed on the exposed section of the lower portion of the sidewall of the fin structure. Dopant is diffused from the doped semiconductor material to a base portion of the fin structure.

Abstract: A phase change memory includes a substrate, a plurality of first phase change elements on the substrate, a plurality of electrodes on the plurality of first phase change elements, and a second phase change element connecting the plurality of electrodes and disposed between the plurality of first phase change elements.

Abstract: A phase change memory, system, and method for gradually changing the conductance and resistance of the phase change memory while preventing resistance drift. The phase change memory may include a phase change material. The phase change memory may also include a bottom electrode. The phase change memory may also include a heater core proximately connected to the bottom electrode. The phase change memory may also include a set of conductive rings surrounding the heater core, where the set of conductive rings comprises one or more conductive rings, and where the set of conductive rings are proximately connected to the phase change material. The phase change memory may also include a set of spacers, where a spacer, from the set of spacers, separates a portion of a conductive ring, from the set of conductive rings, from the heater core.

Abstract: A method of forming a semiconductor device that includes forming a fin structure from a bulk semiconductor substrate and forming an isolation region contacting a lower portion of a sidewall of the fin structure, wherein an upper portion of the sidewall of the fin structure is exposed. A sacrificial spacer is formed on the upper portion of the sidewall of the fin structure. The isolation regions are recessed to provide an exposed section of the sidewall of the fin structure. A doped semiconductor material is formed on the exposed section of the lower portion of the sidewall of the fin structure. Dopant is diffused from the doped semiconductor material to a base portion of the fin structure.

Abstract: The density of deuterium or hydrogen within phase change material (PCM) of a PCM memory cell reduces the active defects in the amorphous phase of the PCM by passivating dangling bonds, which results in the PCM becoming easier to nucleate during the SET process of the PCM memory cell. Resultingly, the addition of deuterium or hydrogen within the PCM relatively increases the SET programming voltage window of the PCM memory cell compared with a similar PCM cell without.

Abstract: Aspects of the invention include systems and methods configured to provide parasitic capacitance-aware dummy metal fill methodologies. A non-limiting example computer-implemented method includes selecting one or more layers in a circuit design layout for interlayer parasitic capacitance reduction. One or more dummy metal shapes in each of the one or more layers selected for interlayer parasitic capacitance reduction is adjusted (e.g., trimmed, moved, and/or reshaped). One or more adjusted dummy metal shapes are modified until the circuit design layout satisfies design rule checking (DRC) analysis and timing is closed.

Abstract: A mushroom memory cell may be formed by depositing a second dielectric layer on top of a first dielectric layer and a heater, depositing a hard mask on top of the second dielectric layer, performing a directional reactive-ion etching to remove an exposed portion of the second dielectric layer, performing a lateral etching to remove a portion of the second dielectric layer under the hard mask, performing directional deposition of a phase change material (PCM) over the heater, depositing a covering dielectric over the PCM, performing a second directional etching to expose a top surface of the PCM, and depositing a top electrode on the surface of the PCM.

Abstract: A semiconductor device is provided. The semiconductor device includes a heater formed on a substrate; a hardmask formed on the heater; a phase change material layer formed on a first side of the heater and the hardmask; a first electrode formed on the phase change material layer on the first side; and a second electrode formed on the substrate on a second side of the heater and the hardmask.

Abstract: Semiconductor device layout designs for Vt tuning are provided. In one aspect, a semiconductor device is provided. The semiconductor device includes: at least one first metal line in contact with a source or drain of an FET; at least one second metal line in contact with a gate of the FET, wherein the first metal line crosses the second metal line; and an oxygen diffusion blocking layer on top of the at least one first metal line in an overlap area of the at least one first metal line and the at least one second metal line. A method of forming a semiconductor device is also provided.

Abstract: A phase change memory element including at least one phase change material layer, and a heater conductor, wherein at least a portion of the heater conductor is circumferentially surrounded by the at least one phase change material layer. The phase change memory element is symmetrical. The phase change memory element can include a top electrode circumferentially surrounding and connected to the at least one phase change material layer, and a bottom electrode in contact with the heater conductor. The phase change memory element can include at least one resistive liner in contact with the at least one phase change material layer.

Abstract: Techniques for forming a metastable phosphorous P-doped silicon Si source drain contacts are provided. In one aspect, a method for forming n-type source and drain contacts includes the steps of: forming a transistor on a substrate; depositing a dielectric over the transistor; forming contact trenches in the dielectric that extend down to source and drain regions of the transistor; forming an epitaxial material in the contact trenches on the source and drain regions; implanting P into the epitaxial material to form an amorphous P-doped layer; and annealing the amorphous P-doped layer under conditions sufficient to form a crystalline P-doped layer having a homogenous phosphorous concentration that is greater than about 1.5×1021 atoms per cubic centimeter (at./cm3). Transistor devices are also provided utilizing the present P-doped Si source and drain contacts.

Abstract: A phase change memory (PCM) cell includes a first electrode, a heater electrically connected to the first electrode, a PCM material electrically connected to the heater, a second electrode electrically connected to the PCM material, and a resistive liner in direct contact with and electrically connected to a sidewall of the heater and to the PCM material.

Abstract: A phase change memory, system, and method for gradually changing the conductance and resistance of the phase change memory while preventing resistance drift. The phase change memory may include a phase change material. The phase change memory may also include a bottom electrode. The phase change memory may also include a heater core proximately connected to the bottom electrode. The phase change memory may also include a set of conductive rings surrounding the heater core, where the set of conductive rings comprises one or more conductive rings, and where the set of conductive rings are proximately connected to the phase change material. The phase change memory may also include a set of spacers, where a spacer, from the set of spacers, separates a portion of a conductive ring, from the set of conductive rings, from the heater core.

Abstract: A method of forming a semiconductor device that includes forming a fin structure from a bulk semiconductor substrate and forming an isolation region contacting a lower portion of a sidewall of the fin structure, wherein an upper portion of the sidewall of the fin structure is exposed. A sacrificial spacer is formed on the upper portion of the sidewall of the fin structure. The isolation regions are recessed to provide an exposed section of the sidewall of the fin structure. A doped semiconductor material is formed on the exposed section of the lower portion of the sidewall of the fin structure. Dopant is diffused from the doped semiconductor material to a base portion of the fin structure.

Abstract: A phase change memory (PCM) cell includes a first electrode, a heater electrically connected to the first electrode, a PCM material electrically connected to the heater, a second electrode electrically connected to the PCM material, and a resistive liner in direct contact with and electrically connected to a sidewall of the heater and to the PCM material.

Abstract: A method of forming a semiconductor device that includes forming a fin structure from a bulk semiconductor substrate and forming an isolation region contacting a lower portion of a sidewall of the fin structure, wherein an upper portion of the sidewall of the fin structure is exposed. A sacrificial spacer is formed on the upper portion of the sidewall of the fin structure. The isolation regions are recessed to provide an exposed section of the sidewall of the fin structure. A doped semiconductor material is formed on the exposed section of the lower portion of the sidewall of the fin structure. Dopant is diffused from the doped semiconductor material to a base portion of the fin structure.

Abstract: Semiconductor device layout designs for Vt tuning are provided. In one aspect, a semiconductor device is provided. The semiconductor device includes: at least one first metal line in contact with a source or drain of an FET; at least one second metal line in contact with a gate of the FET, wherein the first metal line crosses the second metal line; and an oxygen diffusion blocking layer on top of the at least one first metal line in an overlap area of the at least one first metal line and the at least one second metal line. A method of forming a semiconductor device is also provided.

Abstract: A semiconductor structure including a bottom source drain region arranged on a substrate, a semiconductor channel region extending vertically upwards from a top surface of the bottom source drain region, a metal gate disposed on and around the semiconductor channel region, and a top source drain region above the semiconductor channel region and comprising a first doped epitaxy region and a second doped epitaxy region.

Abstract: A method is presented for forming a germanium (Ge) laser diode with direct bandgap for laser generation. The method includes forming an intrinsic Ge active layer over a substrate, forming a p+ region and an n+ region adjacent the intrinsic Ge active layer, such that the p+ region, the n+ region, and the intrinsic Ge active layer collectively define a p-i-n diode, and forming metal contacts to the p+ and n+ regions.

Abstract: Self-aligned gate/junction for VTFET devices are provided. In one aspect, a method of forming a VTFET device includes: forming a stack on a wafer including a first c-SiGe layer, a c-Si layer, and a second c-SiGe layer, wherein the first c-SiGe layer serves as a bottom source/drain; forming fin hardmasks on the stack; partially recessing the second c-SiGe layer to form a fin(s) in the second c-SiGe layer, wherein the second c-SiGe layer that is partially recessed/fin(s) serve as a top source/drain; amorphizing the c-Si layer to form a-Si regions in between c-Si regions that serve as vertical channels; selectively removing the a-Si regions to form gate trenches; forming bottom/top spacers in the gate trenches; and forming gates in the gate trenches that are offset from the bottom/top source/drain by the bottom/top spacers. A VTFET device is also provided. The VTFET device is suitable for 3D monolithic integrated circuits.