An antifuse structure including an opening through a dielectric material to a contact surface and an antifuse material layer present within the opening. The antifuse material layer may be a phase change material alloy of tantalum and nitrogen, wherein at least a base surface of the antifuse material layer is present on the contact surface and sidewall surfaces of the antifuse material layer are present on sidewalls of the opening through the dielectric material. An airgap or solid material core may be in the opening atop the base surface of the phase change material alloy. An electrically conductive material may be in direct contact with at least the antifuse material layer.

Embodiments herein provide film stacks that include a buffer layer; a synthetic ferrimagnet (SyF) coupling layer; and a capping layer, wherein the capping layer comprises one or more layers, and wherein the capping layer, the buffer layer, the SyF coupling layer, or a combination thereof, is not fabricated from Ru.

A method for forming a semiconductor device structure is provided. The method includes forming a first conductive feature over a semiconductor substrate. The method includes forming an oxygen-absorbing layer on a surface of the first conductive feature. The oxygen-absorbing layer absorbs oxygen from the first conductive feature and becomes an oxygen-containing layer. The method includes removing the oxygen-containing layer to expose the surface originally covered by the oxygen-containing layer. The method includes forming a metal-containing layer on the surface. The method includes forming a second conductive feature on the metal-containing layer.

A solid-state imaging device includes: a first electrode formed above a semiconductor substrate; a photoelectric conversion film formed on the first electrode and for converting light into signal charges; a second electrode formed on the photoelectric conversion film; a charge accumulation region electrically connected to the first electrode and for accumulating the signal charges converted from the light by the photoelectric conversion film; a reset gate electrode for resetting the charge accumulation region; an amplification transistor for amplifying the signal charges accumulated in the charge accumulation region; and a contact plug in direct contact with the charge accumulation region, comprising a semiconductor material, and for electrically connecting to each other the first electrode and the charge accumulation region.

The present disclosure provides an integrated circuit structure with dielectric isolation structure for reducing capacitive coupling and crosstalk between conductive features and a method for preparing the same. The method includes: forming a first conductive structure over a substrate; forming a first dielectric structure over the first conductive structure; transforming a sidewall portion of the first conductive structure into a first dielectric portion; removing the first dielectric portion such that a width of the first dielectric structure is greater than a width of a remaining portion of the first conductive structure; forming an inter-layer dielectric (ILD) layer covering a sidewall of the first dielectric structure; forming a reinforcement pillar of energy removable material in the ILD layer; forming a capping dielectric layer over the reinforcement pillar; and performing a thermal process to transform the reinforcement pillar into a dielectric isolation structure including a liner layer enclosing an air gap.

An embodiment includes a substrate, wherein a portion of the substrate extends upwards forming a fin, a gate dielectric over a top surface and at least portions of sidewalls of the fin, a gate electrode over the gate dielectric, and a contact over and extending into the gate electrode, wherein the contact has a first width above the gate electrode and a second width within the gate electrode, the first width being smaller than the second width.

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.

The present disclosure provides methods for forming conductive features in a dielectric layer without using adhesion layers or barrier layers and devices formed thereby. In some embodiments, a structure comprising a dielectric layer over a substrate, and a conductive feature disposed through the dielectric layer. The dielectric layer has a lower surface near the substrate and a top surface distal from the substrate. The conductive feature is in direct contact with the dielectric layer, and the dielectric layer comprises an implant species. A concentration of the implant species in the dielectric layer has a peak concentration proximate the top surface of the dielectric layer, and the concentration of the implant species decreases from the peak concentration in a direction towards the lower surface of the dielectric layer.

Integrated circuitry comprising interconnect metallization on both front and back sides of a gate-all-around (GAA) transistor structure lacking at least one active bottom channel region. Bottom channel regions may be depopulated from a GAA transistor structure following removal of a back side substrate that exposes an inactive portion of a semiconductor fin. During back-side processing, one or more bottom channel region may be removed or rendered inactive through dopant implantation. Back-side processing may then proceed with the interconnection of one or more terminal of the GAA transistor structures through one or more levels of back-side interconnect metallization.

A method for forming a semiconductor contact structure is provided. The method includes depositing a dielectric layer over a substrate. The method also includes etching the dielectric layer to expose a sidewall of the dielectric layer and a top surface of the substrate. In addition, the method includes forming a silicide region in the substrate. The method also includes applying a plasma treatment to the sidewall of the dielectric layer and the top surface of the substrate to form a nitridation region adjacent to a periphery of the silicide region. The method further includes depositing an adhesion layer on the dielectric layer and the silicide region.