Provided are a method of manufacturing a semiconductor device using a thermally decomposable layer, a semiconductor manufacturing apparatus, and the semiconductor device. The method includes forming an etch target layer on a substrate, forming thermally decomposable patterns spaced apart from each other on the etch target layer, forming a first mask pattern covering at least sidewalls of the thermally decomposable patterns, and removing the thermally decomposable patterns by a heating method to expose a sidewall of the first mask pattern.

A semiconductor device includes bit line structures disposed on a substrate, each bit line structure comprising a bit line and an insulating spacer structure, buried contacts which fill lower portions of spaces between bit line structures in the substrate, and landing pads which fill upper portions of the spaces, extend from upper surfaces of the buried contacts to upper surfaces of the bit line structures, and are spaced apart from each other by insulating structures. A first insulating structure is disposed between a first landing pad and a first bit line structure. The first insulating structure includes a sidewall extending along a sidewall of the first landing pad toward the substrate. In a direction extending toward the substrate, the sidewall of the first insulating structure gets closer to a first sidewall of the first bit line structure.

Semiconductor devices include a stack of vertically arranged channel layers. A gate stack is formed above, between, and around the vertically arranged channel layers. Source and drain regions and source and drain conductive contacts are formed. Inner spacers are formed between the vertically arranged channel layers, each having an inner air gap and a recessed layer formed from a first dielectric material. Outer spacers are formed between the gate stack and the source and drain conductive contacts, each having a second dielectric material that is pinched off to form an outer air gap.

A semiconductor device includes a porous dielectric layer including a recessed portion, a conductive layer formed in the recessed portion, and a cap layer formed on the porous dielectric layer and on the conductive layer in the recessed portion, an upper surface of the porous dielectric layer being exposed through a gap in the cap layer.

A microelectronic device comprises pillar structures extending vertically through an isolation material, conductive lines electrically coupled to the pillar structures, contact structures between the pillar structures and the conductive lines, and interconnect structures between the conductive lines and the contact structures. The conductive lines comprise one or more of titanium, ruthenium, aluminum, and molybdenum. The interconnect structures comprise a material composition that is different than one or more of a material composition of the contact structures and a material composition of the conductive lines. Related memory devices, electronic systems, and methods are also described.

Embodiments of the disclosure provide an integrated circuit (IC) structure, including a device layer including a device on a substrate. A local interconnect layer is over the device layer, and includes a first dielectric material over the substrate. The first dielectric material has a first effective dielectric constant. A second dielectric material is over the device and adjacent the first dielectric material. The second dielectric material has a second effective dielectric constant less than the first effective dielectric constant.

A semiconductor structure includes a substrate and a first field effect transistor (FET) formed on the substrate; the first FET includes a first FET first source-drain region, a first FET second source-drain region, a first FET gate between the first and second source-drain regions, and a first FET channel region adjacent the first FET gate and between the first FET first and second source-drain regions. Also included is a buried power rail, buried in the substrate, having a top at a level lower than the first FET channel region, and having buried power rail sidewalls. A first FET shared contact is electrically interconnected with the buried power rail and the first FET second source-drain region, and a first FET electrically isolating region is adjacent the buried power rail sidewalls and separates the buried power rail from the substrate.

Airgap isolation for back-end-of-the-line interconnect structures includes a dielectric liner formed above a top surface and opposite sidewalls of each of a plurality of metal lines on a substrate, the dielectric liner disposed above a top surface of the substrate not covered by the plurality of metal lines, portions of the dielectric liner located on the opposite sidewalls of each of the plurality of metal lines are separated by a space. A dielectric cap is disposed above an uppermost surface of portions of the dielectric liner above each of the plurality of metal lines and above the space, the dielectric cap pinches-off the space between portions of the dielectric liner located on the opposite sidewalls of each of the plurality of metal lines for providing airgaps between adjacent metal lines.

Methods and devices including an air gap adjacent a contact element extending to a source/drain feature of a device are described. Some embodiments of the method include depositing a dummy layer, which is subsequently removed to form the air gap. The dummy layer and subsequent air gap may be formed after a SAC dielectric layer such as silicon nitride is formed over an adjacent metal gate structure.

An electronic device comprising multilevel bitlines comprising first bitlines and second bitlines. The first bitlines and the second bitlines are positioned at different levels. Pillar contacts are electrically connected to the first bitlines and to the second bitlines. Level 1 contacts are electrically connected to the first bitlines and level 2 contacts are electrically connected to the second bitlines. A liner is between the first bitlines and the level 2 contacts. Each bitline of the first bitlines is electrically connected to a single pillar contact in a subblock adjacent to the level 1 contacts and each bitline of the second bitlines is electrically connected to a single pillar contact adjacent to the level 2 contacts. Methods of forming an electronic device and related systems are also disclosed.