Abstract: A semiconductor device includes a bottom electrode contact disposed over one or more of a plurality of conductive lines, magnetoresistive random access memory (MRAM) pillars constructed over the bottom electrode contact, an encapsulation layer section disposed between a pair of the MRAM pillars such that an aspect ratio of a tight pitch gap between the pair of the MRAM pillars is reduced, and a dielectric disposed within the encapsulation layer section, wherein the dielectric fills an entirety of a space defined within the encapsulation layer section. The MRAM pillars have a generally rectangular-shaped or cone-shaped configuration and the encapsulation layer section has a generally U-shaped or V-shaped configuration.

Abstract: A semiconductor structure includes a front-end-of-line level including a plurality of field effect transistors electrically connected to a back-end-of-line interconnect level. The back-end-of-line interconnect level is located on a first side of the front-end-of-line level. A backside power rail is embedded within a backside interlayer dielectric located on a second side of the front-end-of-line level opposing the first side of the front-end-of-line level. The backside power rail is electrically connected to at least one field effect transistor of the plurality of field effect transistors. At least one backside field effect transistor is formed on a first semiconductor layer disposed, at least in part, above a passive device region. A first side of the passive device region is in contact with the first semiconductor layer and a second side of the passive device region, opposing the first side, is in contact with the back-end-of-line interconnect level.

Abstract: A semiconductor structure forms two or more tightly pitched memory devices using a dielectric material for a gap fill material. The approach includes providing two adjacent bottom electrodes in a layer of an insulating material and above a metal layer. Two adjacent pillars are each above one of the two adjacent bottom electrodes where each pillar of the two adjacent pillars is composed of a stack of materials for a memory device. A spacer is around the vertical sides each of the two adjacent pillars. The dielectric material is on the spacer around the vertical sides each of the two adjacent pillars, on the layer of the insulating material between the two adjacent bottom electrodes. The dielectric material fills at least a first portion of a gap between the two adjacent pillars. A low k material covers the dielectric material and exposed portions of the layer of the insulating material.

Abstract: Embodiments of the invention include a transistor comprising a gate region and an epitaxial region, the transistor comprising a frontside opposite a backside.

Abstract: A backside power distribution network is provided having an integrated signal line with a backside connection to a transistor gate. In one aspect, a semiconductor device includes: NFETs and PFETs adjacent to one another on a frontside of a wafer; power rails, connected to source/drain regions of the NFETs and PFETs, present on a backside of the wafer in a space between adjacent NFETs and in a space between adjacent PFETs; and a signal line, connected to a gate of the NFETs and PFETs, present on the backside of the wafer in a space between an adjacent NFET and PFET. The NFETs and PFETs can each include a stack of active layers, and gates surrounding at least a portion of each of the active layers in a gate-all-around configuration. A method of fabricating the present semiconductor devices is provided.

Abstract: Semiconductor devices, and methods of their formation, are provided. The semiconductor device can include a substrate; a wiring level within the substrate; and at least one buried power rail within the wiring level, wherein the at least one buried power rail is divided into a plurality of rail segments, wherein each rail segment of the plurality of rail segments has a length smaller than a total length of the buried power rail.

Abstract: A semiconductor device and formation thereof. The semiconductor device including: a first bottom interconnect formed within a first dielectric layer and located within a logic area of the semiconductor device; a second bottom interconnect formed within the first dielectric layer and located within a memory area of the semiconductor device; and a memory device formed on top of the second bottom interconnect located within the memory area of the semiconductor device, wherein: a first metal material used to form the first bottom interconnect located in the logic area is different than a second metal material used to form the second bottom interconnect located in the memory area.

Abstract: Embodiments of the invention are directed to an integrated circuit (IC) structure that includes a memory element a non-sacrificial hardmask stack over the memory element. The non-sacrificial hardmask stack includes a first hardmask region and a second hardmask region. A compressive stress level of the first hardmask region is greater than a compressive stress level of the second hardmask region.

Abstract: A semiconductor device and formation thereof. The semiconductor device includes a memory device located on top of a first bottom interconnect, wherein the first bottom interconnect is embedded in a first dielectric layer. The semiconductor device further includes a second bottom interconnect embedded in the first dielectric layer, wherein the second bottom interconnect is adjacent to the first bottom interconnect. A top surface of the second bottom interconnect is recessed relative to a top surface of the first bottom interconnect.

Abstract: A semiconductor device includes a bottom electrode contact disposed over one or more of a plurality of conductive lines, magnetoresistive random access memory (MRAM) pillars constructed over the bottom electrode contact, an encapsulation layer section disposed between a pair of the MRAM pillars such that an aspect ratio of a tight pitch gap between the pair of the MRAM pillars is reduced, and a dielectric disposed within the encapsulation layer section, wherein the dielectric fills an entirety of a space defined within the encapsulation layer section. The MRAM pillars have a generally rectangular-shaped or cone-shaped configuration and the encapsulation layer section has a generally U-shaped or V-shaped configuration.

Abstract: A semiconductor structure includes a substrate and a first field effect transistor (FET) formed on the substrate; the first FET includes a first FET first source-drain region, a first FET second source-drain region, a first FET gate between the first and second source-drain regions, and a first FET channel region adjacent the first FET gate and between the first FET first and second source-drain regions. Also included is a buried power rail, buried in the substrate, having a top at a level lower than the first FET channel region, and having buried power rail sidewalls. A first FET shared contact is electrically interconnected with the buried power rail and the first FET second source-drain region, and a first FET electrically isolating region is adjacent the buried power rail sidewalls and separates the buried power rail from the substrate.

Abstract: An electrode structure with an alloy interface is provided. In one aspect, a method of forming a contact structure includes: patterning a via in a first dielectric layer; depositing a barrier layer onto the first dielectric layer, lining the via; depositing and polishing a first metal layer (Element A) into the via to form a contact in the via; depositing a second metal layer (Element B) onto the contact in the via; annealing the first and second metal layers under conditions sufficient to form an alloy AB; depositing a third metal layer onto the second metal layer; patterning the second and third metal layers into a pedestal stack over the contact to form an electrode over the contact, wherein the alloy AB is present at an interface of the electrode and the contact; and depositing a second dielectric that surrounds the pedestal stack. A contact structure is also provided.

Abstract: A semiconductor structure forms two or more tightly pitched memory devices using a dielectric material for a gap fill material. The approach includes providing two adjacent bottom electrodes in a layer of an insulating material and above a metal layer. Two adjacent pillars are each above one of the two adjacent bottom electrodes where each pillar of the two adjacent pillars is composed of a stack of materials for a memory device. A spacer is around the vertical sides each of the two adjacent pillars. The dielectric material is on the spacer around the vertical sides each of the two adjacent pillars, on the layer of the insulating material between the two adjacent bottom electrodes. The dielectric material fills at least a first portion of a gap between the two adjacent pillars. A low k material covers the dielectric material and exposed portions of the layer of the insulating material.

Abstract: A semiconductor device structure includes a metallization stack that has one or more patterned metal layers in a logic area and a memory area. At least one memory device is disposed above the metallization stack. A first level logic metal layer is coupled to a patterned metal layer of the one or more patterned metal layers in the logic area. A first level memory metal layer is formed above the first level logic metal layer and is coupled to a top electrode of the memory device stack. A distance between the one or more patterned metal layers in the logic area and the first level logic metal layer is smaller than the distance between the one or more patterned metal layers in the memory area and the first level memory metal layer.

Abstract: A method for planarizing a metal conductor layer embedded in a dielectric layer is provided. The method includes removing a portion of an overburden of the metal conductor layer that is formed over the dielectric layer with a first CMP slurry. The method also includes removing a remaining portion of the overburden of the metal conductor layer with a second CMP slurry to expose upper portions of the dielectric layer.

Abstract: A via structure and methods for forming a via structure generally includes a via opening in a dielectric layer. A conformal barrier layer is in the via opening; and a conductive metal on the barrier layer in the via opening. The conductive metal includes a recessed top surface. A conductive planarization stop layer is on the recessed top surface and extends about a shoulder portion formed in the dielectric layer, wherein the shoulder portion extends about a perimeter of the via opening. A fill material including an insulator material or a conductor material is on the conductive planarization stop layer within the recessed top surface, wherein the conductive planarization stop layer on the shoulder portion is coplanar to the insulator material or the conductor material. Also described are methods of fabricating the via structure.

Abstract: A via structure and methods for forming a via structure generally includes a via opening in a dielectric layer. A conformal barrier layer is in the via opening; and a conductive metal on the barrier layer in the via opening. The conductive metal includes a recessed top surface. A conductive planarization stop layer is on the recessed top surface and extends about a shoulder portion formed in the dielectric layer, wherein the shoulder portion extends about a perimeter of the via opening. A fill material including an insulator material or a conductor material is on the conductive planarization stop layer within the recessed top surface, wherein the conductive planarization stop layer on the shoulder portion is coplanar to the insulator material or the conductor material. Also described are methods of fabricating the via structure.

Abstract: A novel bevel etch sequence for embedded metal contamination removal from BEOL wafers is provided. In one aspect, a method of processing a wafer includes: performing a bevel dry etch to break up layers of contaminants with embedded metals which, post back-end-of line metallization, are deposited on a bevel of the wafer, which forms a damaged layer on surfaces of the wafer; and then performing a sequence of wet etches, following the bevel dry etch, to render the bevel of the wafer substantially free of contaminants, wherein the sequence of wet etches includes etching the damaged layer to undercut and lift-off any remaining contaminants. A wafer, processed in this manner, having a bevel that is substantially free of contaminants is also provided.

Abstract: An ion beam etching tool comprises a chuck configured to electrostatically receive a wafer; a plasma source configured to introduce an ion beam to the wafer; and a shield on the chuck and configured to shield the chuck from the ion beam. The shield comprises a material that is configured to be one of removable from the wafer or inert with regard to a semiconductor device on the wafer.

Abstract: Back end of line (BEOL) metallization structures and methods generally includes forming a landing pad on an interconnect structure. A multilayer structure including layers of metals and at least one insulating layer are provided on the structure and completely cover the landing pad. The landing pad is a metal-filled via and has a width dimension that is smaller than the multilayer structure, or the multilayer structure and the underlying metal conductor in the interconnect structure. The landing pad metal-filled via can have a width dimension that is sub-lithographic.