A semiconductor device includes a semiconductor substrate having an upper surface with a semiconductor member extending vertically from the upper surface, wherein the semiconductor member has a first conductivity type. A first region of a second conductivity type different than the first conductivity type is formed at a proximal end of the semiconductor member adjacent the upper surface. A second region of the second conductivity type is formed at a distal end of the semiconductor member. A channel region of the semiconductor member extends between the first and second regions. A floating gate laterally wraps around a first portion of the channel region. A control gate laterally wraps around the floating gate. A select gate laterally wraps around a second portion of the channel region. An erase gate laterally wraps around the semiconductor member.

A semiconductor device, includes a source and drain bottom epitaxial layer positioned on top of a dielectric substrate. A metal gate is positioned on top of the bottom epitaxial layer. A source and drain top epitaxial layer is positioned on top of the metal gate. A first and second semiconductor channel pass vertically from the source and drain top epitaxial layer through the metal gate to the source and drain bottom epitaxial layer. First and second metal contacts are conductively coupled to the first and second semiconductor channels. First and second metal vias are formed on a backside of the source and drain bottom epitaxial layer and arranged in conductive contact with the first and second semiconductor channels. A metal layer is formed on a backside of the first and second metal vias.

A semiconductor device includes a buried power rail (BPR) over a substrate and a semiconductor structure over the BPR. The semiconductor structure is tube-shaped and extends along a vertical direction. The semiconductor structure includes a first source/drain (S/D) region over the BPR, a gate region over the first S/D region, and a second S/D region over the gate region. The semiconductor device includes a first S/D interconnect structure extending from the BPR and further into the semiconductor structure such that a top portion of the first S/D interconnect structure is surrounded by the first S/D region. The semiconductor device includes a gate structure that includes (i) a gate oxide formed along an inner surface of the gate region and (ii) a gate electrode formed along sidewalls of the gate oxide in the gate region. The semiconductor device includes a second S/D interconnect structure positioned over the second S/D region.

The present disclosure relates to semiconductor structures and, more particularly, to a device with a vertical nanowire channel region and methods of manufacture. The structure includes: a bottom source/drain region; a top source/drain region; a gate structure extending between the bottom source/drain region and the top source/drain region; and a vertical nanowire in a channel region of the gate structure.

Structures and methods are disclosed in which a layer stack can be formed with a plurality of layers of a metal, where each of the layers of metal can be separated by a layer of a dielectric. An opening in the layer stack can be formed such that a semiconductor layer beneath the plurality of layers of the metal is uncovered. One or more vertical channel structures can be formed within the opening by epitaxial growth. The vertical channel structure can include a vertically oriented transistor. The vertical channel structure can include an interface of a silicide metal with a first metal layer of the plurality of metal layers. The interface can correspond to one of a source or a drain connection of a transistor. The silicide metal can be annealed above a temperature threshold to form a silicide interface between the vertical channel structure and the first metal layer.

Structures and methods that facilitate the formation of gate contacts for vertical transistors constructed with semiconductor pillars and spacer-like gates are disclosed. In a first embodiment, a gate contact rests on an extended gate region, a piece of a gate film, patterned at a side of a vertical transistor at the bottom of the gate. In a second embodiment, an extended gate region is patterned on top of one or more vertical transistors, resulting in a modified transistor structure. In a third embodiment, a gate contact rests on a top surface of a gate merged between two closely spaced vertical transistors. Optional methods and the resultant intermediate structures are included in the first two embodiments in order to overcome the related topography and ease the photolithography. The third embodiment includes alternatives for isolating the gate contact from the semiconductor pillars or for isolating the affected semiconductor pillars from the substrate.

Techniques for area scaling of contacts in VTFET devices are provided. In one aspect, a VTFET device includes: a fin(s); a bottom source/drain region at a base of the fin(s); a gate stack alongside the fin(s); a top source/drain region present at a top of the fin(s); a bottom source/drain contact to the bottom source/drain region; and a gate contact to the gate stack, wherein the bottom source drain and gate contacts each includes a top portion having a width W1.sub.CONTACT over a bottom portion having a width W2.sub.CONTACT, wherein W2.sub.CONTACT<W1.sub.CONTACT, and wherein a sidewall along the top portion is discontinuous with a sidewall along the bottom portion. The bottom portion having the width W2.sub.CONTACT is present alongside the gate stack and the top source/drain region. A method of forming a VTFET device is also provided.

A transistor comprises a top source/drain region, a bottom source/drain region, a channel region vertically between the top and bottom source/drain regions, and a gate operatively laterally-adjacent the channel region. The channel region is crystalline and comprises a plurality of vertically-elongated crystal grains that individually are directly against both of the top source/drain region and the bottom source/drain region. Other embodiments, including methods, are disclosed.

A semiconductor device includes a gate stacking structure that includes a plurality of gate electrodes and a plurality of insulating layers alternately stacked with each other, and a plurality of channel structures that penetrate the gate stacking structure. The plurality of channel structures include a first channel structure that includes a first channel layer, and a plurality of second channel structures adjacent to the first channel structure and that include a plurality of second channel layers. The first channel layer in the first channel structure and the plurality of second channel layers in the plurality of second channel structures have a same crystal orientation.

A memory device includes a vertical transistor including a semiconductor body extending in a first direction. The semiconductor body includes a doped source, a doped drain, and a channel portion. The memory device further includes a storage unit coupled to one of the source and the drain, a word line extending in a second direction perpendicular to the first direction, and a body line coupled to the channel portion of the semiconductor body. The word line is between the storage unit and the body line in the first direction.