The application relates to a semiconductor switch element, including: a first vertical transistor device formed in a substrate and having a source region formed on a first side of the substrate and a drain region formed on a second side of the substrate vertically opposite to the first side; a second vertical transistor device formed laterally aside the first vertical transistor device in the same substrate and having a source region formed on the first side of the substrate and a drain region formed on the second side of the substrate; a conductive element arranged on the second side of the substrate and electrically connecting the drain regions of the vertical transistor devices; and a trench extending vertically into the substrate at the second side of the substrate, wherein at least a part of the conductive element is arranged in the trench.

A method for producing a 3D semiconductor device: providing a first level with a first single crystal layer; forming control circuitry of first transistors in and/or on the first level with a first metal layer above; forming a second metal layer above the first metal layer; forming a third metal layer above the second metal layer; forming at least one second level on top of or above the third metal layer; performing additional processing steps to form a plurality of second transistors within the second level; forming a fourth and fifth metal layers above second level; a global power distribution grid includes fifth metal, and local power distribution grid includes the second metal layer, where the fifth metal layer thickness is at least 50% greater than the second metal layer thickness.

Some embodiments include an integrated assembly having first and second pillars of semiconductor material laterally offset from one another. The pillars have source/drain regions and channel regions vertically offset from the source/drain regions. Gating structures pass across the channel regions, and extend along a first direction. An insulative structure is over regions of the first and second pillars, and extends along a second direction which is crosses the first direction. Bottom electrodes are coupled with the source/drain regions. Leaker-device-structures extend upwardly from the bottom electrodes. Ferroelectric-insulative-material is laterally adjacent to the leaker-device-structures and over the regions of the bottom electrodes. Top-electrode-material is over the ferroelectric-insulative-material and is directly against the leaker-device-structures. Some embodiments include methods of forming integrated assemblies.

A semiconductor device includes a semiconductor structure formed on a substrate, a gate formed on a first side of the semiconductor structure, and a charge collector layer formed on a second side of the semiconductor structure.

Embodiments of the invention are directed to a semiconductor structure that includes a first fin structure having a first sidewall, a first gate structure adjacent a lower portion of the first sidewall, and a first spacer structure over the first gate structure and adjacent an upper portion of first the sidewall. The first spacer structure includes a first spacer structure thickness dimension that extends in a first direction away from the first sidewall. The first gate structure includes a first gate structure thickness dimension that extends in the first direction away from the first sidewall. The first gate structure dimension is about equal to the first spacer structure thickness dimension.

A method of forming a fin field effect transistor (finFET) having fin(s) with reduced dimensional variations, including forming a dummy fin trench within a perimeter of a fin pattern region on a substrate, forming a dummy fin fill in the dummy fin trench, forming a plurality of vertical fins within the perimeter of the fin pattern region, including border fins at the perimeter of the fin pattern region and interior fins located within the perimeter and inside the bounds of the border fins, wherein the border fins are formed from the dummy fin fill, and removing the border fins, wherein the border fins are dummy fins and the interior fins are active vertical fins.

A semiconductor arrangement and method of forming the same are described. A semiconductor arrangement includes a third metal connect in contact with a first metal connect in a first active region and a second metal connect in a second active region, and over a shallow trench isolation region located between the first active region and a second active region. A method of forming the semiconductor arrangement includes forming a first opening over the first metal connect, the STI region, and the second metal connect, and forming the third metal connect in the first opening. Forming the third metal connect over the first metal connect and the second metal connect mitigates RC coupling.

A semiconductor structure and a method a method of forming a vertical FET (Field-Effect Transistor), includes growing a bottom source-drain layer of a second type on a substrate of a first type, growing a channel layer on the bottom source-drain layer, forming a first fin from the channel layer with mask on top of the first fin. A width of the mask is wider than a final first fin width.

Techniques regarding anchors for fins comprised within stacked VTFET devices are provided. For example, one or more embodiments described herein can comprise an apparatus, which can further comprise a fin extending from a semiconductor body. The fin can be comprised within a stacked vertical transport field effect transistor device. The apparatus can also comprise a dielectric anchor extending from the semiconductor body and adjacent to the fin. Further, the dielectric anchor can be coupled to the fin.

A technique relates to a semiconductor device. A source/drain layer is formed. Fins with gate stacks are formed in a fill material, a dummy fin template including at least one fin of the fins and at least one gate stack of the gate stacks, the fins being formed on the source/drain layer. A trench is formed through the fill material by removing the dummy fin template, such that a portion of the source/drain layer is exposed in the trench. A source/drain metal contact is formed on the portion of the source/drain layer in the trench.