Abstract: Techniques are provided to fabricate semiconductor devices. For example, a method includes forming a lower level interconnect line having a first hardmask layer thereon and embedded in a lower level dielectric layer. The first hardmask layer is removed to form a first opening having a first width in the lower level dielectric layer. The sidewalls of the lower level dielectric layer are etched in the first openings to form a second opening having a second width. The second width is greater than the first width. An upper level interconnect line is formed on the lower level interconnect line.

Abstract: RMG techniques for VFET formation using a chamfering process are provided. In one aspect, a method of forming a VFET device includes: patterning fins adjacent to one another in a substrate; forming bottom source/drains at a base of the fins; forming bottom spacers over the bottom source/drains; forming sacrificial gates alongside the fins; forming top source/drains at a top of the fins; forming top spacers surrounding the top source/drains; removing the sacrificial gates; depositing a high-? gate dielectric along sidewalls of the fins; removing the high-? gate dielectric from an opening between adjacent top spacers; depositing at least a first workfunction-setting metal layer onto the high-? gate dielectric; removing the first workfunction-setting metal layer from the opening between the adjacent top spacers; and depositing at least a second workfunction-setting metal layer onto the first workfunction-setting metal layer to form replacement metal gates. A VFET device is also provided.

Abstract: Integrated chips and methods of forming the same include forming upper dummy lines over lower conductive lines. The lower conductive lines are recessed to form conductive vias between the lower conductive lines and the upper dummy lines. The upper dummy lines are replaced with upper conductive lines that contact the conductive vias.

Abstract: Embodiments of the present invention are directed to techniques for providing an novel field effect transistor (FET) architecture that includes a center fin region and one or more vertically stacked nanosheets. In a non-limiting embodiment of the invention, a nanosheet stack is formed over a substrate. The nanosheet stack can include one or more first semiconductor layers and one or more first sacrificial layers. A trench is formed by removing a portion of the one or more first semiconductor layers and the one or more first sacrificial layers. The trench exposes a surface of a bottommost sacrificial layer of the one or more first sacrificial layers. The trench can be filled with one or more second semiconductor layers and one or more second sacrificial layers such that each of the one or more second semiconductor layers is in contact with a sidewall of one of the one or more first semiconductor layers.

Abstract: Techniques are provided to fabricate semiconductor devices. For example, a method includes forming an interconnect structure having a base, a first conductive metal layer disposed on the base; and a first hardmask layer disposed on the first conductive metal layer. Metal lines are formed by subtractive etching. The metal lines have negative tapered sidewalk, and an opening is formed between adjacent metal lines. A first interlevel dielectric layer is deposited in the openings. A portion of the first interlevel dielectric layer is removed to form trench openings having positive tapered sidewalls. A dielectric layer is deposited in one of the openings. A liner layer and a second conducting metal layer are deposited in the other trench openings. The liner layer and the second conductive metal layer are recessed. A second hardmask layer is deposited on a top surface of the liner layer and the second conductive metal layer.

Abstract: A method of forming a vertical metal-air transistor device is provided. The method includes forming a precursor stack with a stack template on the precursor stack on a substrate. The method further includes forming a bottom spacer on the substrate around the precursor stack, and depositing a liner casing on the precursor stack. The method further includes depositing a conductive gate layer on the bottom spacer and liner casing. The method further includes reducing the size of the stack template to form a template post on the precursor stack, and forming a stack cap on the template post and precursor stack.

Abstract: Methods for forming semiconductor devices are disclosed including forming a semiconductor structure having a semiconductor substrate containing two or more fins. The method includes etching a first optical planarization layer on the semiconductor structure exposing a top surface of each of a gate spacer, a gate cap layer and a portion of a source/drain contact adjacent to the exposed gate spacer to form a first gate contact opening. The method further includes depositing a sacrificial place-holder material in the first gate contact opening. The method further includes removing the first optical planarization layer. The method further includes recessing a first conductive material.

Abstract: Techniques are provided to fabricate semiconductor devices. For example, a method includes forming an interconnect structure having a base, a first conductive metal layer disposed on the base; and a first hardmask layer disposed on the first conductive metal layer. Metal lines are formed by subtractive etching. The metal lines have negative tapered sidewalls, and an opening is formed between adjacent metal lines. A first interlevel dielectric layer is deposited in the openings. A portion of the first interlevel dielectric layer is removed to form trench openings having positive tapered sidewalls. A dielectric layer is deposited in one of the openings. A liner layer and a second conducting metal layer are deposited in the other trench openings. The liner layer and the second conductive metal layer are recessed. A second hardmask layer is deposited on a top surface of the liner layer and the second conductive metal layer.

Abstract: An integrated semiconductor device having a gate structure adjacent to a semiconductor body at a channel region, the channel region being positioned laterally between source/drain regions. Metal plugs are on the source/drain regions, and rectangular-shaped or trapezoidal-shaped plug caps are above and immediately adjacent to the metal plugs. A self-aligned metal filled contact (CA) is conductively coupled to one of the metal plugs on the source and drain regions, and a self-aligned metal filled contact (CBoA) is conductively coupled to the gate structure. The device further includes a low k dielectric layer that includes a continuous airgap having an inverted u-shape formed about the gate structure and breaks at about a portion of the gate structure including the self-aligned metal filled contact (CBoA). Also, methods for forming the device including the uniquely shaped continuous airgap are disclosed.

Abstract: A method for fabricating a semiconductor device including an ion-sensitive field-effect transistor (ISFET) with enhanced sensitivity includes forming a microwell within a stack including alternating dielectric layers formed on a semiconductor chip corresponding to an ISFET. Forming the stack includes forming a first dielectric layer including a first material and a second dielectric layer including a second material. The method further includes etching the second dielectric layer selective to at least the first dielectric layer using a wet etch process, and forming a macrowell from the microwell having a shape defined by the etching.

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 provided which includes forming a semiconductor substrate having one or more fins. The method includes forming over the fins a plurality of gate structures. The method includes forming gate spacers on sidewalls of the gate structure. The method includes forming a source/drain region on the semiconductor substrate between each adjacent gate spacer. The method includes depositing an interlevel dielectric layer on the source/drain regions and over the gate structures. The method includes depositing a hardmask on the interlevel dielectric layer. The method includes patterning the hardmask to form a plurality of openings and exposing the top surface of each of the source/drain regions. The method includes depositing an optical planarization layer in a portion of the openings and above the top surface of the gate structures. The method includes etching the interlevel dielectric layer in the opening to form an undercut region below the hardmask.

Abstract: A semiconductor structure includes at least one non-self-aligned contact in a metallization layer and a fabrication method for forming the same are disclosed. The method includes forming gate metal in a gate stack on a substrate and forming a source-drain contact in a source-drain stack on the substrate. The gate stack and the source-drain stack are separated by a sidewall spacer. The method recesses the sidewall spacer thereby forming a trench. In the trench, a first outer metal liner and a second outer metal liner are recessed, horizontally enlarging the trench to form a widened trench over respective top surfaces of the recessed first outer metal liner, second outer metal liner, and sidewall spacer. The method then deposits dielectric material filling the widened trench and contacting the first inner metal core, the second inner metal core, the first outer metal liner, the second outer metal liner, and the sidewall spacer.

Abstract: An interconnect structure includes an interlayer dielectric (ILD) having a cavity extending therethrough along a first direction. A first electrically conductive strip is formed on a substrate and within the cavity. The first electrically conductive strip extends along the first direction and across an upper surface of the substrate. A second electrically conductive strip is on an upper surface of the ILD and extends along a second direction opposite the first direction. A fully aligned via (FAV) extends between the first and second electrically conductive strips such that all sides of the FAV are co-planar with opposing sides of the first electrically conductive strip and opposing sides of the second electrically conductive strip thereby providing a FAV that is fully aligned with the first electrically conductive strip and the second electrically conductive strip.

Abstract: Structures for air-gap spacers in a field-effect transistor and methods for forming air-gap spacers in a field-effect transistor. A gate structure is formed on a top surface of a semiconductor body. A dielectric spacer is formed adjacent to a vertical sidewall of the gate structure. A semiconductor layer is formed on the top surface of the semiconductor body. The semiconductor layer is arranged relative to the vertical sidewall of the gate structure such that a first section of the first dielectric spacer is located in a space between the semiconductor layer and the vertical sidewall of the gate structure. A second section of the dielectric spacer that is located above a top surface of the semiconductor layer is removed. An air-gap spacer is formed in a space from which the second section of the dielectric spacer is removed.

Abstract: Embodiments of the present invention are directed to forming a wrap-around contact (WAC) for a vertical field effect transistor (VFET). In a non-limiting embodiment of the invention, a top spacer is formed on a surface of a gate. A sacrificial spacer is formed on the top spacer. A source/drain region is formed over the top spacer and between sidewalls of the sacrificial spacer. The sacrificial spacer can be replaced with a wrap-around contact. The source/drain region can include a first material, the sacrificial spacer can include a second material, and the second material can be selected such that the second material can be etched selective to the first material.

Abstract: A gate-all-around field effect transistor (GAAFET) and method. The GAAFET includes nanosheets, a gate around center portions of the nanosheets, and inner spacers aligned below end portions. The nanosheet end portions are tapered from the source/drain regions to the gate and the inner spacers are tapered from the gate to the source/drain regions. Each inner spacer includes: a first spacer layer, which has a uniform thickness and extends laterally from the gate to an adjacent source/drain region; a second spacer layer, which fills the space between a planar top surface of the first spacer layer and a tapered end portion of the nanosheet above; and, for all but the lowermost inner spacers, a third spacer layer, which is the same material as the second spacer layer and which fills the space between a planar bottom surface of the first spacer layer and a tapered end portion of the nanosheet below.

Abstract: Vertical field effect transistor (VFET) structures and methods of fabrication include a bottom spacer having a uniform thickness. The bottom spacer includes a bilayer portion including a first layer formed of an oxide, for example, and a second layer formed of a nitride, for example, on the first layer, and a monolayer portion of a fourth layer of a nitride for example, immediately adjacent to and intermediate the fin and the bilayer portion.

Abstract: An apparatus includes a substrate having a base and a plurality of pillars extending from the base where the pillars are configured to define a nano-array, a dielectric disposed on the base, and a plasmonic coating disposed on a surface of the dielectric and on one or more of the pillars.

Abstract: A gate-all-around field effect transistor (GAAFET) and method. The GAAFET includes nanosheets, a gate around center portions of the nanosheets, and inner spacers aligned below end portions. The nanosheet end portions are tapered from the source/drain regions to the gate and the inner spacers are tapered from the gate to the source/drain regions. Each inner spacer includes: a first spacer layer, which has a uniform thickness and extends laterally from the gate to an adjacent source/drain region; a second spacer layer, which fills the space between a planar top surface of the first spacer layer and a tapered end portion of the nanosheet above; and, for all but the lowermost inner spacers, a third spacer layer, which is the same material as the second spacer layer and which fills the space between a planar bottom surface of the first spacer layer and a tapered end portion of the nanosheet below.