A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate. In the method, sacrificial spacer layers are formed on the plurality of fins, and portions of the semiconductor substrate located under the sacrificial spacer layers and located at sides of the plurality of fins are removed. Bottom source/drain regions are grown in at least part of an area where the portions of the semiconductor substrate were removed, and sacrificial epitaxial layers are grown on the bottom source/drain regions. The method also includes diffusing dopants from the bottom source/drain regions and the sacrificial epitaxial layers into portions of the semiconductor substrate under the plurality of fins. The sacrificial epitaxial layers are removed, and bottom spacers are formed in at least part of an area where the sacrificial epitaxial layers were removed.

A vertical transport field-effect transistor array includes continuous spacers at cell edges that are formed following a replacement metal gate process. Techniques for fabricating the transistor array include forming trenches extending along the fin edges of the array to provide access to sacrificial gates, replacing the sacrificial gates with gate stacks, and forming the continuous spacers to encapsulate the gate stacks once formed. Removal of interlevel dielectric material from the array is not required for gate replacement. Bottom source/drain contacts may be formed in the trenches and in adjoining relation to the continuous spacers.

A method for producing a 3D semiconductor device: providing a first level with a first single crystal layer; forming a plurality 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 a first etch step; performing additional processing steps to form a plurality of second transistors within the second level; forming a fourth metal layer above; forming a connection to the second metal layer which includes a via through the second level; forming a fifth metal layer above, where some second transistors include a metal gate, and the fifth metal layer thickness is at least 50% greater than the second metal layer thickness.

Methods, devices, systems, and apparatus for three-dimensional semiconductor structures are provided. In one aspect, a semiconductor device includes: a semiconductor substrate, multiple conductive layers vertically stacked on the semiconductor substrate, and multiple transistors. The multiple conductive layers include a first conductive layer, a second conductive layer, and a third conductive layer that are sequentially stacked together. The multiple transistors include a first transistor and a second transistor in the first conductive layer and a third transistor in the third conductive layer. Each transistor includes a first terminal, a second terminal, and a gate terminal. First terminals of the first, second, and third transistors are conductively coupled to a first conductive node in the second conductive layer.

A method for manufacturing a semiconductor device includes forming a plurality of fins on a semiconductor substrate. In the method, at least two spacer layers are formed around a first fin of the plurality of fins, and a single spacer layer is formed around a second fin of the plurality of fins. The at least two spacer layers include a first spacer layer including a first material and a second spacer layer including a second material different from the first material. The single spacer layer includes the second material. The method also includes selectively removing part of the first spacer layer to expose part the first fin, and epitaxially growing a source/drain region around the exposed part of the first fin.

A semiconductor device includes a semiconductor layer of first-conductivity-type that has a main surface and that includes an active region set at the main surface, a current detection region set at the main surface away from the active region, and a boundary region set in a region between the active region and the current detection region at the main surface, a first body region of second-conductivity-type formed in a surface layer portion of the main surface at the active region, a first trench gate structure formed in the main surface at the active region, a second body region of second-conductivity-type formed in the surface layer portion of the main surface at the current detection region, a second trench gate structure formed in the main surface at the current detection region, a well region of second-conductivity-type formed in the surface layer portion of the main surface at the boundary region, and a dummy trench gate structure formed in an electrically floating state in the main surface at the boundary region.

Embodiments of the present invention are directed to forming an airgap-based vertical field effect transistor (VFET) without structural collapse. A dielectric collar anchors the structure while forming the airgaps. In a non-limiting embodiment of the invention, a vertical transistor is formed over a substrate. The vertical transistor can include a fin, a top spacer, a top source/drain (S/D) on the fin, and a contact on the top S/D. A dielectric layer is recessed below a top surface of the top spacer and a dielectric collar is formed on the recessed surface of the dielectric layer. Portions of the dielectric layer are removed to form a first cavity and a second cavity. A first airgap is formed in the first cavity and a second airgap is formed in the second cavity. The dielectric collar anchors the top S/D to the top spacer while forming the first airgap and the second airgap.

Provided is a first vertical field effect transistor in which first source regions and first connection portions via which a first body region is connected to a first source electrode are disposed alternately and cyclically in a first direction in which first trenches extend. In a second direction orthogonal to the first direction, Lxm≤Lxr≤0.20 μm holds true where Lxm denotes a distance between adjacent first trenches and Lxr denotes the inner width of a first trench. The lengths of the first connection portions are in a convergence region in which the on-resistance of the vertical field effect transistor at the time when a voltage having a specification value is applied to first gate conductors to supply current having a specification value does not decrease noticeably even when the lengths of the first connection portions are made much shorter.

A method for manufacturing a vertical transistor device includes forming a plurality of fins on a substrate, and forming a gate dielectric layer on the fins and on the substrate adjacent the fins. In the method, one or more sacrificial layers are formed on the gate dielectric layer, and portions of the gate dielectric layer and the one or more sacrificial layers are removed to define a plurality of gate regions. The method also includes depositing a dielectric fill layer in gaps left by the removed gate dielectric and sacrificial layers, and selectively removing the remaining portions of the one or more sacrificial layers to form a plurality of vacant areas in the gate regions. First and second gate structures are respectively formed in first and second vacant areas of the plurality of vacant areas. The first and second gate structures are recessed to a uniform height.

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.