A capacitor includes a lower electrode including a first metal material and having a first crystal size in a range of a few nanometers, a dielectric layer covering the lower electrode and having a second crystal size that is a value of a crystal expansion ratio times the first crystal size and an upper electrode including a second metal material and covering the dielectric layer. The upper electrode has a third crystal size smaller than the second crystal size.

Some embodiments include a memory device having a buried wordline, a shield plate, and an access device. The access device includes first and second diffusion regions and a channel region. The diffusion regions and the channel region are arranged vertically so that the channel region is between the first and second diffusion regions. The wordline is adjacent to a first side surface of the channel region, and the shield plate is adjacent to a second side surface of the channel region; with the first and second side surfaces being in opposing relation to one another. Some embodiments include methods of forming integrated assemblies.

A method of manufacturing a memory structure is provided. The method includes forming a first gate structure, a second gate structure, and a plurality of source/drain regions in a substrate, in which the plurality of source/drain regions are disposed on opposite sides of the first gate structure and the second gate structures; performing a dry etching process to form a trench between the first gate structure and the second gate structure; performing a wet etching process to expand the trench, in which the expanded trench has a hexagonal shaped cross section profile; and forming a bit line contact in the expanded trench.

A non-conformal, highly selective liner for etch methods in semiconductor devices is described. A method comprises forming a film stack on a substrate; etching the film stack to form an opening; depositing a non-conformal liner in the opening; etching the non-conformal liner from the bottom of the opening; and selectively etching the film stack relative to the non-conformal liner to form a logic or memory hole. The non-conformal liner comprises one or more of boron, carbon, or nitrogen.

The present disclosure relates to a method for preparing a semiconductor device with air gaps between conductive lines (e.g., bit lines). The method includes forming a first dielectric structure and a second dielectric structure over a semiconductor substrate, and forming a conductive material over the first dielectric structure and the second dielectric structure. The conductive material extends into a first opening between the first dielectric structure and the second dielectric structure. The method also includes partially removing the conductive material to form a first bit line and a second bit line in the first opening and forming a sealing dielectric layer over the first bit line and the second bit line such that an air gap is formed between the sealing dielectric layer and the semiconductor substrate.

Semiconductor devices may include an active pattern, a gate structure in an upper portion of the active pattern, a bit line structure on the active pattern, a lower spacer structure on a lower portion of a sidewall of the bit line structure, and an upper spacer structure on an upper portion of the sidewall of the bit line structure. The lower spacer structure includes first and second lower spacers sequentially stacked, the first lower spacer contacts the lower portion of the sidewall of the bit line structure and does not include nitrogen, and the second lower spacer includes a material different from the first lower spacer. A portion of the upper spacer structure contacting the upper portion of the sidewall of the bit line structure includes a material different from the first lower spacer.

Disclosed herein is an apparatus that includes: first and second wiring patterns extending in a first direction, first and second transistors arranged adjacent to each other, and third to sixth wiring patterns extending in a second direction. The third wiring pattern is connected between the first wiring pattern and one of source/drain regions of the first transistor, the fourth wiring pattern is connected between the second wiring pattern and other of source/drain regions of the first transistor, the fifth wiring pattern is connected to one of source/drain regions of the second transistor, the fifth wiring pattern overlapping with the first wiring pattern, the sixth wiring pattern is connected to other of source/drain regions of the second transistor, the sixth wiring pattern overlapping with the second wiring pattern. The third and fourth wiring patterns are greater in width in the first direction than the fifth and sixth wiring patterns.

The present disclosure relates to a semiconductor memory device and a method of fabricating the same, and the semiconductor memory device includes a substrate, an active structure and a shallow trench isolation. The active structure is disposed within the substrate and includes a first active region and a second active region. The first active region includes a plurality of active region units, and the second active region is disposed at an outer side of the first active region to directly connect to a portion of the active region units. The second active region includes a plurality of first openings disposed an edge of the second active region. The shallow trench isolation is disposed within the substrate, to surround the active structure.

Disclosed are apparatus comprising a substrate and techniques for fabricating the same. The substrate may include a first metal layer having signal interconnects on a first side of the substrate. A second metal layer may include ground plane portions on a second side of the substrate. Conductive channels may be formed in the substrate and coupled to the ground plane portions. The conductive channels are configured to extend the ground plane portions towards the signal interconnects to reduce a distance from individual signal interconnects to individual conductive channels. The distance may be in a range of seventy-five percent to fifty percent of a substrate thickness between the first metal layer and the second metal layer.

Semiconductor devices and corresponding methods of manufacturing the same are disclosed. For example, a semiconductor device includes a first transistor comprising a first channel region. The first channel region includes one or more first nanostructures formed of a semiconductor material. The semiconductor device includes a second transistor disposed vertically with respect to the first transistor and comprising a second channel region. The second channel region includes one or more second nanostructures formed of a conductive oxide material.