Abstract: Self-aligned semiconductor FET device source and drain contacts and techniques for formation thereof are provided. In one aspect, a semiconductor FET device includes: at least one gate disposed on a substrate; source and drains on opposite sides of the at least one gate; gate spacers offsetting the at least one gate from the source and drains; lower source and drain contacts disposed on the source and drains; upper source and drain contacts disposed on the lower source and drain contacts; and a silicide present between the lower source and drain contacts and the upper source and drain contacts.

Abstract: The present disclosure relates to semiconductor structures and, more particularly, to contact structures and methods of manufacture. The method includes: recessing an isolation region between adjacent gate structures and below metallization overburden of source/drain metallization; planarizing the metallization overburden to a level of the adjacent gate structures; and forming source/drain contacts to the source/drain metallization, on sides of and extending above the adjacent gate structures.

Abstract: A method for forming a semiconductor device includes forming a structure having at least a first nanosheet stack for a first device, a second nanosheet stack for a second device and disposed over the first nanosheet stack, a disposable gate structure, and a gate spacer. The disposable gate structure and sacrificial layers of the first and second nanosheet stacks are removed thereby forming a plurality of cavities. A conformal gate dielectric layer is formed in the plurality cavities and surrounding at least portions of the first and second nanosheet stacks. A first conformal work function layer is formed in contact with the gate dielectric layer. Portions of the first conformal work function layer are removed without using a mask from at least the second nanosheet stack. A second conformal work function layer is formed on exposed portions of the gate dielectric layer.

Abstract: Dual damascene interconnect structures with fully aligned via integration schemes are formed using different dielectric materials having different physical properties. A low-k dielectric material having good fill capabilities fills nanoscopic trenches in such structures. Another dielectric material forms the remainder of the dielectric portion of the interconnect layer and has good reliability properties, though not necessarily good trench filling capability. The nanoscopic trenches may be filled with a flowable polymer using flowable chemical vapor deposition. A further dielectric layer having good reliability properties is deposited over the metal lines and dual damascene patterned to form interconnect line and via patterns. The patterned dielectric layer is filled with interconnect metal, thereby forming interconnect lines and fully aligned via conductors. The via conductors are electrically connected to previously formed metal lines below.

Abstract: A dual damascene interconnect structure with a fully aligned via integration scheme is formed with a partially removed etch stop layer. Portions of the etch stop layer are removed prior to dual damascene patterning of an interlevel dielectric layer formed above metal lines and after such patterning. Segments of the etch stop layer remain only around the vias, allowing the overall capacitance of the structure to be reduced.

Abstract: Interconnect structures and methods for forming the interconnect structures generally include a subtractive etching process to form a fully aligned top via and metal line interconnect structure. The interconnect structure includes a top via and a metal line formed of an alternative metal other than copper or tungsten. A conductive etch stop layer is intermediate the top via and the metal line. The top via is fully aligned to the metal line.

Abstract: Scalable device designs for FINFET technology are provided. In one aspect, a method of forming a FINFET device includes: patterning fins in a substrate which include a first fin(s) corresponding to a first FINFET device and a second fin(s) corresponding to a second FINFET device; depositing a conformal gate dielectric over the fins; depositing a conformal sacrificial layer over the gate dielectric; depositing a sacrificial gate material over the sacrificial layer; replacing the sacrificial layer with a first workfunction-setting metal(s) over the first fin(s) and a second workfunction-setting metal(s) over the second fin(s); removing the sacrificial gate material; forming dielectric gates over the first workfunction-setting metal(s), the second workfunction-setting metal(s) and the gate dielectric forming gate stacks; and forming source and drains in the fins between the gate stacks, wherein the source and drains are separated from the gate stacks by inner spacers. A FINFET device is also provided.

Abstract: A method for manufacturing a semiconductor device includes forming an interconnect in a first dielectric layer, and forming a second dielectric layer on the first dielectric layer. In the method, an etch stop layer is formed on the second dielectric layer, and a third dielectric layer is formed on the etch stop layer. A trench and an opening are formed in the third and second dielectric layers, respectively. A barrier layer is deposited in the trench and in the opening, and on a top surface of the interconnect. The method also includes removing the barrier layer from the top surface of the interconnect and from a bottom surface of the trench, and depositing a conductive fill layer in the trench and in the opening, and on the interconnect. A bottom surface of the trench includes the etch stop layer.

Abstract: A device and a method to produce an augmented-laser (ATLAS) comprising a bi-stable resistive system (BRS) integrated in series with a semiconductor laser. The laser exhibits reduction/inhibition of the Spontaneous Emission (SE) below lasing threshold by leveraging the abrupt resistance switch of the BRS. The laser system comprises a semiconductor laser and a BRS operating as a reversible switch. The BRS operates in a high resistive state in which a semiconductor laser is below a lasing threshold and emitting in a reduced spontaneous emission regime, and a low resistive state in which a semiconductor laser is above or equal to a lasing threshold and emitting in a stimulated emission regime. The BRS operating as a reversible switch is electrically connected in series across two independent chips or on a single wafer. The BRS is formed using insulator-to-metal transition (IMT) materials or is formed using threshold-switching selectors (TSS).

Abstract: A first mask layer is formed on top of a semiconductor substrate. A mandrel material is formed perpendicular to the first mask layer. A second mask layer is formed on one or more exposed surfaces of the mandrel material. The mandrel material is removed. A pattern of the first mask layer and the second mask layer is transferred into the semiconductor substrate.

Abstract: An embodiment of the invention may include a semiconductor structure and method of manufacturing. The semiconductor structure may include a top channel and a bottom channel, wherein the top channel includes a plurality of vertically oriented channels. The bottom channel includes a plurality of horizontally oriented channels. The semiconductor structure may include a gate surrounding the top channel and the bottom channel. The semiconductor structure may include spacers located on each side of the gate. A first spacer includes a dielectric material located between the plurality of vertically oriented channels. A second spacer includes a dielectric material located between the plurality of horizontally oriented channels. This may enable spacer formation between the vertical spacers.

Abstract: Self-aligned semiconductor FET device source and drain contacts and techniques for formation thereof are provided. In one aspect, a semiconductor FET device includes: at least one gate disposed on a substrate; source and drains on opposite sides of the at least one gate; gate spacers offsetting the at least one gate from the source and drains; lower source and drain contacts disposed on the source and drains; upper source and drain contacts disposed on the lower source and drain contacts; and a silicide present between the lower source and drain contacts and the upper source and drain contacts.

Abstract: Embodiments of the invention are directed to a method of performing fabrication operations to form a transistor, wherein the fabrication operations include forming a source or drain (S/D) region having stacked, spaced-apart, and doped S/D layers. The fabrication operations further include forming a multi-region S/D contact structure configured to contact a top surface, a bottom surface, and sidewalls of each of the stacked, spaced-apart, and doped S/D layers.

Abstract: Embodiments of the invention are directed to a method of performing fabrication operations to form a transistor, wherein the fabrication operations include forming a source or drain (S/D) region having stacked, spaced-apart, and doped S/D layers. The fabrication operations further include forming a multi-region S/D contact structure configured to contact a top surface, a bottom surface, and sidewalls of each of the stacked, spaced-apart, and doped S/D layers.

Abstract: A method for manufacturing a semiconductor device includes forming a plurality of gate structures on a semiconductor fin, and forming a plurality of source/drain regions adjacent the plurality of gate structures. In the method, a germanium oxide layer is formed on the plurality of gate structures and on the plurality of source/drain regions, and portions of the germanium oxide layer on the plurality of source/drain regions are converted into a plurality of dielectric layers. The method also includes removing unconverted portions of the germanium oxide layer from the plurality of gate structures, and depositing a plurality of cap layers in place of the removed unconverted portions of the germanium oxide layer. The plurality of dielectric layers are removed, and a plurality of source/drain contacts are formed on the plurality of source/drain regions. The plurality of source/drain contacts are adjacent the plurality of cap layers.

Abstract: A method includes forming a first metallization layer on a substrate comprising a plurality of conductive lines. The method further includes forming a first dielectric layer on the substrate and between adjacent conductive lines. The method further includes forming a first via layer comprising at least one via in the first dielectric layer and exposing a top surface of at least one of the plurality of conductive lines. The method further includes depositing a first conductive material in the first via. The method further includes forming a barrier layer on a top surface of the first dielectric layer and exposing a top surface of the plurality of conductive lines and the first conductive material.

Abstract: An interconnect structure includes a first electrically conductive via portion on an upper surface of a substrate, the first electrically conductive via elongated along a first direction, and a first ILD material on the substrate and covering the first electrically conductive via portion. The first ILD material includes an ILD upper surface exposing a via surface of the first electrically conductive via portion. A second electrically conductive via portion is on the ILD upper surface and the via upper surface thereby defining a contact area between the first electrically conductive via portion and the second electrically conductive via portion. The second electrically conductive via portion elongated along a second direction orthogonal with respect to the first direction. A second ILD material is on the ILD upper surface to cover the second electrically conductive via portion. The first and second electrically conductive via portions are fully aligned at the contact area.

Abstract: Methods and structures for pitch multiplication include forming a plurality of mandrel lines and non-mandrel lines on a target layer, wherein the non-mandrel lines include a protective spacer material about a top sidewall portion and a first spacer material about a lower sidewall portion, wherein the protective spacer material has a different etch selectivity than the first spacer material. The plurality of mandrel lines and non-mandrel lines are transferred into the target layer.

Abstract: A method of forming a vertical transistor is provided. The method includes forming a first set of vertical fins in a first row on a first bottom source/drain layer, and a second set of vertical fins in a second row on a second bottom source/drain layer, wherein the vertical fins in the same row are separated by a spacing with a sidewall-to-sidewall distance, SD, and the vertical fins in the same column of adjacent rows are separated by a gap having a gap distance, GD. The method further includes forming a gate metal layer on the first set of vertical fins and the second set of vertical fins, wherein the gate metal layer does not fill in the gap between vertical fins in the same column, and forming a cover layer plug in the remaining gap after forming the gate metal layer.

Abstract: A method is presented for reducing capacitance coupling. The method includes forming a nanosheet stack including alternating layers of a first material and a second material over a substrate, forming a source/drain epi for a first device, depositing a sacrificial material over the source/drain epi, forming a source/drain epi for a second device over the sacrificial material, and removing the sacrificial material to define an airgap directly between the source/drain epi for the first device and the source/drain epi for the second device.