Techniques are disclosed for forming vertical transistor architectures. In accordance with some embodiments, a semiconductor layer is disposed over a lower interconnect layer and patterned into a plurality of vertical semiconductor bodies (e.g., nanowires and/or other three-dimensional semiconductor structures) in a regular, semi-regular, or irregular array, as desired for a given target application or end-use. Thereafter, a gate layer surrounding the active channel portion of each (or some sub-set) of the vertical semiconductor bodies is formed, followed by an upper interconnect layer, in accordance with some embodiments. During processing, a given vertical semiconductor body optionally may be removed and, in accordance with some embodiments, either: (1) blanked to provide a dummy channel; or (2) replaced with an electrically conductive plug to provide a via or other inter-layer routing. Processing can be performed in multiple iterations, for example, to provide multi-level/stacked vertical transistor circuit architectures of any standard and/or custom configuration.

The present disclosure includes memory having a continuous channel, and methods of processing the same. A number of embodiments include forming a vertical stack having memory cells connected in series between a source select gate and a drain select gate, wherein forming the vertical stack includes forming a continuous channel for the source select gate, the memory cells, and the drain select gate, and removing a portion of the continuous channel for the drain select gate such that the continuous channel is thinner for the drain select gate than for the memory cells and the source select gate.

Disclosed are a semiconductor device, a manufacturing method therefor, and an electronic equipment, the semiconductor device includes: at least one vertical channel transistor disposed on a base substrate, and a bit line; the transistor includes a semiconductor pillar extending along a direction perpendicular to the base substrate, the semiconductor pillar includes a channel region, and a first region and a second region respectively disposed on two sides of the channel region, the second region is disposed between the base substrate and the first region, the bit line is in contact with the second region, and a plasma dopant concentration of a contact surface between the second region and the bit line is greater than or equal to 1e14 atoms/square centimeter.

A method includes forming a buried layer in a substrate, growing an epitaxial layer over the substrate, etching the epitaxial layer and the buried layer to form a first trench and a second trench, wherein the first trench and the second trench are of a same depth and a width of the second trench is greater than a width of the first trench, forming a dielectric layer in a bottom portion of the first trench, forming a first gate electrode in an upper portion of the first trench and filling the second trench with a gate electrode material, forming gate electrodes for a plurality of lateral transistors formed in the substrate, forming a body region, forming a first drain/source region over the body region and forming a second drain/source region over the epitaxial layer.

A semiconductor device includes a semiconductor body having a first surface and a second surface opposite to the first surface, first trenches and second trenches extending from the first surface into the semiconductor body, at least one lateral IGFET including a first load terminal at the first surface, a second load terminal at the first surface and a gate electrode within the first trenches, and at least one vertical IGFET including a first load terminal at the first surface, a second load terminal at the second surface and a gate electrode within the second trenches. The first trenches extend from the first surface into the semiconductor body deeper than a channel zone of the lateral IGFET and confine the channel zone.

An integrated device includes a semiconductor well formed in an epitaxial layer, and a guard ring formed in the epitaxial layer and surrounding the semiconductor well. The semiconductor well and the guard ring include a type of semiconductor different from that of the epitaxial layer. The integrated device also includes an insulating layer formed atop the guard ring, and multiple gate electrodes formed on a top surface of the insulating layer, overlapping the guard ring and surrounding the semiconductor well. The gate electrodes include a first gate electrode and a second gate electrode separated by a gap. An intersecting line between the top surface of the insulating layer and a side wall of the first gate electrode partially overlaps an area that is defined based on an intersecting line between the top surface of the insulating layer and a side wall of the second gate electrode above the guard ring.

One semiconductor device includes one parallel transistor for connecting in parallel multiple vertical transistors disposed in an active region on a semiconductor substrate. The parallel transistor includes semiconductor pillars that project out in a direction perpendicular to a main surface of the semiconductor substrate; a lower diffusion layer that is disposed below the semiconductor pillars; upper diffusion layers that are each disposed on an upper section of the semiconductor pillars; and gate electrodes disposed, with a gate insulator film therebetween, on the entire side surfaces of the semiconductor pillars. The upper diffusion layers are connected to one upper contact plug that is disposed over the upper diffusion layers.

First and second transistors with different electrical characteristics are supported by a substrate having a first-type dopant. The first transistor includes a well region within the substrate having the first-type dopant, a first body region within the well region having a second-type dopant and a first source region within the first body region and laterally offset from the well region by a first channel. The second transistor includes a second body region within the semiconductor substrate layer having the second-type dopant and a second source region within the second body region and laterally offset from material of the substrate by a second channel having a length greater than the length of the first channel. A gate region extends over portions of the first and second body regions for the first and second channels, respectively.

Semiconductor devices are disclosed. A semiconductor device may include a hybrid transistor configured in a vertical orientation. The hybrid transistor may include a gate electrode, a drain material, a source material, and a channel material operatively coupled between the drain material and the source material. The source material and the drain material include a first material, and the channel material includes a second, different material.

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.