A semiconductor device includes a subtractive skip via technique in which a relatively high aspect ratio (HAR) skip via is fabricated within a lower aspect ratio (LAR) skip via opening. A metal fill is formed within the LAR skip via opening. Undesired portions of the metal fill region are removed, a retained portion or portion thereof forms the HAR skip via, and/or retained portions thereof forms multiple HAR skip vias, or the like. After forming these substrative via(s), a dielectric backfill may be formed therearound within the remaining LAR skip via opening. This backfill dielectric may be selected to reduce shorting propensities between the substrative via(s) and respective one or more wiring structures in a lower level, in a higher level, and/or the skipped level(s).

A semiconductor storage device includes a semiconductor substrate and a conductive layer separated from the semiconductor substrate in a first direction. The conductive layer extends in a second direction parallel to the semiconductor substrate. A semiconductor layer extends in the first direction through the conductive layer. A first contact extends in the first direction and is connected to a surface of the conductive layer facing away from the semiconductor substrate. A first insulating layer extends in the first direction, and a second insulating layer extends along the first insulating layer in the first direction. Each of the first and second insulating layers entirely overlaps with the first contact when viewed in the first direction.

A method of forming an electrical contact in a semiconductor structure includes performing a patterning process to form a mask on a semiconductor structure, the semiconductor structure comprising a first semiconductor region, a second semiconductor region, a dielectric layer having a first opening over the first semiconductor region and a second opening over the second semiconductor region, wherein the mask covers an exposed surface of the second semiconductor region within the second opening, performing an amorphization ion implant process to amorphize an exposed surface of the first semiconductor region within the first opening, performing a removal process to remove the mask, performing a selective epitaxial deposition process, to epitaxially form a contact layer on the exposed surface of the second semiconductor region, and performing a recrystallization anneal process to recrystallize the amorphized surface of the first semiconductor region.

A conductor-filled via formed in a staircase structure that is provided in conjunction with a 3-dimensional array of memory strings, where the staircase structure includes multiple steps with each step including a bit line layer and a source line layer. The conductor-filled via includes a conductor to electrically connect a top layer in a first step in the staircase structure to a buried contact provided under the staircase structure, the top layer being the bit line layer or the source line layer of the first step; and a spacer insulator lining the sidewalls of the conductor-filled via to isolate the conductor from at least a bottom layer of the first step and the bit line layer or the source line layer in any steps between the first step and the buried contact.

A microelectronic device comprises a stack structure comprising insulative structures vertically interleaved with conductive structures, first support pillar structures vertically extending through the stack structure in a first staircase region including steps defined at edges of tiers of the insulative structures and conductive structures, and second support pillar structures vertically extending through the stack structure in a second staircase region including additional steps defined at edges of additional tiers of the insulative structures and conductive structures, the second support pillar structures having a smaller cross-sectional area than the first support pillar structures. Related memory devices, electronic systems, and methods are also described.

A semiconductor structure includes a fin structure formed over a substrate. The structure also includes a gate structure formed across the fin structure. The structure also includes source/drain epitaxial structures formed on opposite sides of the gate structure. The structure also includes an inter-layer dielectric (ILD) structure formed over the gate structure. The structure also includes a contact blocking structure formed through the ILD structure over the source/drain epitaxial structure. A lower portion of the contact blocking structure is surrounded by an air gap, and the air gap is covered by a portion of the ILD structure.

Some embodiments include apparatuses and methods of forming the apparatuses. One of the apparatuses includes a first dielectric material; a second dielectric material separated from the first dielectric material; a memory cell string including a pillar extending through the first and second dielectric materials, the pillar including a portion between the first and second dielectric materials; an additional dielectric material contacting the portion of the pillar; a conductive material contacting the additional dielectric material; and a tungsten structure including a portion of tungsten contacting the conductive material, wherein a majority of the portion of tungsten is beta-phase tungsten.

An interconnection structure includes a first interconnection layer and a second interconnection layer. The first interconnection layer includes a conductive feature extending through a first dielectric layer. The second interconnection layer includes a metal contact and at least one conductive structure extending through a second dielectric layer formed over the first interconnection layer. The metal contact is configured to overlay and interconnect with the conductive feature. A portion of the conductive feature closest to the conductive structure is recessed with a depth a from a top surface of the conductive feature.

A method of forming an electrical contact in a semiconductor structure includes performing a patterning process to form a mask on a semiconductor structure, the semiconductor structure comprising a first semiconductor region, a second semiconductor region, a dielectric layer having a first opening over the first semiconductor region and a second opening over the second semiconductor region, wherein the mask covers an exposed surface of the second semiconductor region within the second opening, performing an amorphization ion implant process to amorphize an exposed surface of the first semiconductor region within the first opening, performing a removal process to remove the mask, performing a selective epitaxial deposition process, to epitaxially form a contact layer on the exposed surface of the second semiconductor region, and performing a recrystallization anneal process to recrystallize the amorphized surface of the first semiconductor region.

A semiconductor structure includes a substrate and a back end of line (BEOL) layer disposed on the substrate. The BEOL layer includes a first dielectric layer, a via conductive portion, a second dielectric layer and a liner. The first dielectric layer has a surface and a via-hole extends from the surface. The via conductive portion is disposed within the via-hole and has a recess recessed relative to the surface. The second dielectric layer is disposed on the first dielectric layer, wherein the second dielectric layer has a metal-trench exposing the recess. The liner is disposed on a sidewall of the metal-trench and separated from the via conductive portion.