Abstract: Techniques for selective CD shrink for source and drain contact trench to optimize FET device performance are provided. In one aspect, a semiconductor FET device includes: at least one gate; source and drains on opposite sides of the at least one gate; recesses in the source and drains; and metal contacts disposed over the source and drains and in the recesses, wherein the metal contacts are in direct contact with a bottom and sidewalls of each of the recesses in both a first direction and a second direction, wherein the first direction is perpendicular to the at least one gate, and wherein the second direction is parallel to the at least one gate. A method of forming a semiconductor FET device is also provided.

Abstract: An interconnect structure is provided. The interconnect structure includes first conducting lines and second conducting lines. The first conducting lines are formed of a first metallic material and include at least one individual first conducting line in contact with a first corresponding substrate conducting line. The second conducting lines are formed of a second metallic material and include at least one individual second conducting line between neighboring first conducting lines and in contact with a second corresponding substrate conducting line. The at least one individual second conducting line is separated from each of the neighboring first conducting lines by controlled distances.

Abstract: A method of via formation including forming a sacrificial mask over a conductive layer, forming a plurality of pillars in the sacrificial mask and the conductive layer, wherein each pillar of the plurality of pillars includes a sacrificial cap and a first conductive via, depositing a spacer between the plurality of pillars, masking at least one of the sacrificial caps, removing at least one of the sacrificial caps to create openings, forming second conductive vias in the openings, and depositing a dielectric coplanar to a top surface of the second conductive vias.

Abstract: A semiconductor device is provided. The semiconductor device includes a bottom epitaxial layer, a gate stack formed over the bottom epitaxial layer, the gate stack including a work function metal (WFM) layer, a channel fin formed on the bottom epitaxial layer, a first interlayer dielectric (ILD) layer formed in a gate landing area over the gate stack, a second ILD layer formed in an area other than the gate landing area, and a WFM encapsulation layer formed between the first ILD layer and the second ILD layer, and formed on sidewalls of the gate stack.

Abstract: Alternating copolymers having hydrocarbon-substituted terminal units and repeat units each containing two different monomer units with extreme ultraviolet (EUV)-absorbing elements are disclosed. Alternating copolymers having organic terminal units and repeat units each containing a monomer unit with an EUV-absorbing element and an organic monomer unit are also disclosed. A process of forming a polymer resist, which includes providing an alternating copolymer having repeat units with at least one EUV-absorbing monomer unit and replacing end groups of the alternating copolymer with unreactive terminal units, is disclosed as well.

Abstract: A high-density resistive random-access memory array with self-aligned bottom electrode contact includes a plurality of electrically conductive structures embedded in an interconnect dielectric material layer, a bottom electrode selectively grown over, and electrically connected to, each of the electrically conductive structures with the bottom electrode above an electrically conductive structure being separated from the bottom electrode above another electrically conductive structure by a first dielectric filling layer, the bottom electrode having a semi-circular shape. The array further includes a resistive random-access memory pillar disposed above the bottom electrode.

Abstract: A semiconductor device structure and a method for fabricating the same. The semiconductor device structure includes an embedded memory device and an electrode in contact with a top surface of the memory embedded device. A metal encapsulation layer is in contact with a top surface of the electrode and a portion of sidewalls of the electrode. The metal encapsulation layer comprises one or more materials that are chemical etch resistant and are conductive when oxidized. The method includes forming an insulating layer over a memory device and an electrode in contact with the memory device. Portions of the insulating layer are etched. The etching exposes a top surface and a portion of sidewalls of the electrode. A metal encapsulation layer is formed over and in contact with the top surface and the portion of sidewalls of the electrode.

Abstract: Embodiments of the present invention are directed to fabrication method and resulting structures for placing self-aligned top vias at line ends of an interconnect structure. In a non-limiting embodiment of the invention, a line feature is formed in a metallization layer of an interconnect structure. The line feature can include a line hard mask. A trench is formed in the line feature to expose line ends of the line feature. The trench is filled with a host material and a growth inhibitor is formed over a first line end of the line feature. A via mask is formed over a second line end of the line feature. The via mask can be selectively grown on an exposed surface of the host material. Portions of the line feature that are not covered by the via mask are recessed to define a self-aligned top via at the second line end.

Abstract: A semiconductor device structure includes a metallization stack comprising one or more patterned metal layers. A bi-layer dielectric cap is disposed on and in contact with the metallization stack. At least one memory device is disposed on the bi-layer dielectric cap. A method for forming the metallization stack includes receiving a structure comprising a metallization layer and a first dielectric cap layer formed over the metallization layer. The metallization layer includes a logic area and a memory area. At least one memory stack is formed over the first dielectric cap layer. A self-assembled monolayer is formed over and in contact with the memory stack. A second dielectric cap layer is formed on and in contact with the first dielectric cap layer. The second dielectric cap layer is not formed on the self-assembled monolayer.

Abstract: Methods are presented for forming multi-threshold field effect transistors. The methods generally include depositing and patterning an organic planarizing layer to protect underlying structures formed in a selected one of the nFET region and the pFET region of a semiconductor wafer. In the other one of the nFET region and the pFET region, structures are processed to form an undercut in the organic planarizing layer. The organic planarizing layer is subjected to a reflow process to fill the undercut. The methods are effective to protect a boundary between the nFET region and the pFET region.

Abstract: One or more embodiments described herein include systems, and/or methods that facilitate fabrication of a semiconductor device using a spacer lithography-etch process. According to an embodiment, a method can comprise performing a first lithography exposure and etch over a first layer of a semiconductor device, where the first lithography exposure and etch comprises forming one or more mandrels on a first region of a second layer by employing a first photoresist layer. The method can further comprise forming one or more spacers on a sidewall of the one or more mandrels and covering a second region of the second layer, where the second region is adjacent to the one or more mandrels. The method can further comprise forming a cut over a third region of the second layer and filling the third region with first material.

Abstract: A semiconductor device structure and a method for fabricating the same. The semiconductor device structure includes an embedded memory device and an electrode in contact with a top surface of the memory embedded device. A metal encapsulation layer is in contact with a top surface of the electrode and a portion of sidewalls of the electrode. The metal encapsulation layer comprises one or more materials that are chemical etch resistant and are conductive when oxidized. The method includes forming an insulating layer over a memory device and an electrode in contact with the memory device. Portions of the insulating layer are etched. The etching exposes a top surface and a portion of sidewalls of the electrode. A metal encapsulation layer is formed over and in contact with the top surface and the portion of sidewalls of the electrode.

Abstract: A semiconductor substrate has a metal via in the substrate, and has, on the substrate, a metal line that is less than 8 nanometers (nm) wide and at least 20 nm tall. A method for making a semiconductor structure includes forming a metal via in a substrate; forming a mandrel atop and offset from the via; depositing a metal-containing liner onto the mandrel; exposing the top of the mandrel by anisotropically etching the liner, thereby defining a separate portion of the liner at each side of the mandrel; and growing a metal line on each portion of the liner.

Abstract: A method includes forming a first semiconducting channel comprising a plurality of vertical nanowires and a second semiconducting channel comprising a plurality of vertical nanowires. The first semiconducting channel and the second semiconducting channel are formed in a stacked configuration. The plurality of vertical nanowires of the first semiconducting channel are formed in alternating positions relative to the plurality of vertical nanowires of the second semiconducting channel.

Abstract: A memory device is provided. The memory device includes a memory stack on a first dielectric layer, and a sidewall spacer on the memory stack. The memory device further includes a conductive cap on the sidewall spacer and the memory stack and an upper metal line on the conductive cap and the sidewall spacer, wherein the upper metal line wraps around the conductive cap, sidewall spacer, and memory stack.

Abstract: A semiconductor device structure includes a metallization stack comprising one or more patterned metal layers. A bi-layer dielectric cap is disposed on and in contact with the metallization stack. At least one memory device is disposed on the bi-layer dielectric cap. A method for forming the metallization stack includes receiving a structure comprising a metallization layer and a first dielectric cap layer formed over the metallization layer. The metallization layer includes a logic area and a memory area. At least one memory stack is formed over the first dielectric cap layer. A self-assembled monolayer is formed over and in contact with the memory stack. A second dielectric cap layer is formed on and in contact with the first dielectric cap layer. The second dielectric cap layer is not formed on the self-assembled monolayer.

Abstract: An initial semiconductor structure includes an underlying substrate, a hard mask stack, an organic planarization layer (OPL), a first complementary material, and a patterned photoresist layer patterned into a plurality of photoresist pillars defining a plurality of photoresist trenches. The first material is partially etched inward of the trenches, to provide trench regions, and the photoresist is removed. The trench regions are filled with a second complementary material, preferentially etchable with respect to the first material. A polymer brush is grafted on the second material but not the first material, to form polymer brush regions with intermediate regions not covered by the brush. The first material is anisotropically etched the at the intermediate regions but not the brush regions. The OPL is etched inward of the intermediate regions, to provide a plurality of OPL pillars defining a plurality of OPL trenches inverted with respect to the photoresist pillars.

Abstract: A method of forming a semiconductor structure includes forming a first array of mandrels on a hardmask layer disposed on an uppermost surface of a semiconductor substrate. First sidewall image transfer spacers are formed on opposing longitudinal sidewalls of each mandrel in the first array of mandrels. A second array of mandrels is formed on the hardmask layer. Each mandrel in the second array of mandrels is laterally separated from each mandrel in the first array of mandrels by the first sidewall image transfer spacers. Second sidewall image transfer spacers are formed on opposing transversal sidewalls of the first array of mandrels and the second array of mandrels. Portions of the second sidewall image transfer spacers are selectively removed to define a crosslink fin pattern to be transferred to the semiconductor substrate.

Abstract: A method of manufacturing a semiconductor device is provided. The method includes forming a plurality of metal lines on substrate, forming a sacrificial dielectric material layer between the metal lines, forming a hardmask over at least one of the metal lines, etching at least one of the metal lines that is not covered by the hardmask, treating the sacrificial dielectric material layer to soften the layer. The method also includes removing the treated sacrificial dielectric material layer.

Abstract: A semiconductor structure includes a set of mandrel lines and a set of non-mandrel lines disposed on a hardmask in an alternating pattern. Spacers are disposed between adjacent mandrel lines and non-mandrel lines. The spacers include a composition which exhibits an etch rate greater than an etch rate of the mandrel lines and the non-mandrel lines.