A device includes a substrate, a gate structure over the substrate, gate spacers on opposite sidewalls of the gate structure, source/drain structures over the substrate and on opposite sides of the gate structure, and a self-assemble monolayer (SAM) in contact with an inner sidewall of one of the gate spacer and in contact with a top surface of the gate structure.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a fin comprising silicon, the fin having a lower fin portion and an upper fin portion. A first insulating layer is directly on sidewalls of the lower fin portion of the fin, wherein the first insulating layer is a non-doped insulating layer comprising silicon and oxygen. A second insulating layer is directly on the first insulating layer directly on the sidewalls of the lower fin portion of the fin, the second insulating layer comprising silicon and nitrogen. A dielectric fill material is directly laterally adjacent to the second insulating layer directly on the first insulating layer directly on the sidewalls of the lower fin portion of the fin.

Interconnect structures are disclosed. An example includes conductive traces over a first dielectric layer, dielectric helmet structures over top surfaces of the conductive traces, and a second dielectric layer over the helmet structures. Spaces between adjacent ones of conductive traces are devoid of material. A bottom surface of the second dielectric layer is between top surfaces of the dielectric structures and bottom surfaces of the helmet structures, or co-planar with the top surface of the helmet structures, but the airgap extends above tops of the conductive traces. Another example includes a dielectric adjacent to upper sections but not lower sections of conductive traces, so as to provide airgaps between adjacent lower sections. Alternatively, a first dielectric material is adjacent the upper sections and a second compositionally different dielectric material is adjacent the lower sections. In either case, the sidewalls of the upper sections of the interconnect features may include scalloping.

Embodiments of the disclosure are in the field of advanced integrated circuit structure fabrication and, in particular, 10 nanometer node and smaller integrated circuit structure fabrication and the resulting structures. In an example, an integrated circuit structure includes a fin comprising silicon, the fin having a lower fin portion and an upper fin portion. A first insulating layer is directly on sidewalls of the lower fin portion of the fin, wherein the first insulating layer is a non-doped insulating layer comprising silicon and oxygen. A second insulating layer is directly on the first insulating layer directly on the sidewalls of the lower fin portion of the fin, the second insulating layer comprising silicon and nitrogen. A dielectric fill material is directly laterally adjacent to the second insulating layer directly on the first insulating layer directly on the sidewalls of the lower fin portion of the fin.

A semiconductor memory device according to an embodiment, includes a semiconductor pillar extending in a first direction, a first electrode extending in a second direction crossing the first direction, a second electrode provided between the semiconductor pillar and the first electrode, a first insulating film provided between the semiconductor pillar and the second electrode, a second insulating film provided between the first electrode and the second electrode and on two first-direction sides of the first electrode, and a conductive film provided between the second electrode and the second insulating film, the conductive film not contacting the first insulating film.

A system and method for fabricating on-die metal-insulator-metal capacitors capable of maintaining a similar capacitance for design reuse across multiple semiconductor fabrication processes are described. In various implementations, an integrated circuit includes multiple metal-insulator-metal (MIM) capacitors. The MIM capacitors are formed between two signal nets. The integrated circuit includes multiple intermediate metal layers (or metal plates) formed between two signal nets. Subsequent semiconductor fabrication processes typically increase a number of metal plates that can be formed in the dielectric layer, such as an oxide layer, between two signal nets. To permit design reuse across multiple semiconductor fabrication processes, for a particular MIM capacitor designated to maintain a same capacitance, the additional metal plates for the particular MIM capacitor are formed as floating nets. Additionally, the same electrode plates of the particular MIM capacitor are used across the multiple semiconductor fabrication processes.

A linear mark extending perpendicular to a primary step direction of stepped terrace for a three-dimensional memory device can be employed as a reference feature for aligning a trimming material layer before initiating an etch-and-trim process sequence. The linear mark can be formed as a linear trench or a linear rail structure. The distance between a sidewall of each trimming material layer and the linear mark can be measured at multiple locations that are laterally spaced apart perpendicular to the primary step direction to provide statistically significant data points, which can be employed to provide an enhanced control of the staircase patterning process. Likewise, locations of patterned stepped surfaces can be measured at multiple locations to provide enhanced control of the locations of vertical steps in the stepped terrace.

A method used in forming integrated circuitry comprises forming conductive line structures having conductive vias laterally between and spaced longitudinally along immediately-adjacent of the conductive line structures. First insulating material is formed laterally between immediately-adjacent of the conductive vias. Second insulating material is formed directly above the first insulating material and directly above the conductive vias. The second insulating material comprises silicon, carbon, nitrogen, and hydrogen. A third material is formed directly above the second insulating material. The third material and the second insulating material comprise different compositions relative one another. The third material is removed from being directly above the second insulating material and the thickness of the second insulating material is reduced thereafter. A fourth insulating material is formed directly above the second insulating material of reduced thickness. A plurality of electronic components is formed above the fourth insulating material and that individually are directly electrically coupled to individual of the conductive vias through the fourth and second insulating materials. Other embodiments, including structure, are disclosed.

Photodefinable alignment layers for chemical assisted patterning and approaches for forming photodefinable alignment layers for chemical assisted patterning are described. An embodiment of the invention may include disposing a chemically amplified resist (CAR) material over a hardmask that includes a switch component. The CAR material may then be exposed to form exposed resist portions. The exposure may produces acid in the exposed portions of the CAR material that interact with the switch component to form modified regions of the hardmask material below the exposed resist portions.

A method provides a design layout having a pattern of features. The design layout is transferred onto a substrate on a semiconductor substrate using a mask. A scanning parameter is determined based on the design layout. An image of the substrate is generated using the determined scanning parameter. A substrate defect is identified by comparing a first number of closed curves in a region of the image and a second number of polygons in a corresponding region of the design layout.