Semiconductor structures having a source contact and a drain contact that exhibit reduced contact resistance and methods of forming the same are disclosed. In one embodiment of the present application, the reduced contact resistance is provided by forming a layer of a dipole metal or metal-insulator-semiconductor (MIS) oxide between an epitaxial semiconductor material (providing the source region and the drain region of the device) and an overlying metal semiconductor alloy. In yet other embodiment, the reduced contact resistance is provided by increasing the area of the source region and drain region by patterning the epitaxial semiconductor material that constitutes at least an upper portion of the source region and drain region of the device.

A heating device includes a heating assembly. The heating assembly includes a ventilation structure configured to blow gas to an edge of a to-be-processed workpiece carried by the heating device. The heating device further includes a base arranged on a side of the heating assembly away from a heating surface of the heating assembly. A mounting space is formed between the base and the heating assembly. The heating device also includes a cooling mechanism arranged in the mounting space, located at a position corresponding to an edge area of the heating surface, and configured to cool the heating assembly.

A vertical field effect transistor (VFET) device and a method of manufacturing the same are provided. The method includes: (a) providing an intermediate VFET structure comprising a substrate, and fin structures, gate structures and bottom epitaxial layers on the substrate, the gate structures being formed on the fin structures, respectively, each fin structure comprising a fin and a mask thereon, and the bottom epitaxial layers; (b) filling interlayer dielectric (ILD) layers between and at sides of the gate structures; (c) forming an ILD protection layer on the ILD layers, respectively, the ILD protection layer having upper portions and lower portions, and comprising a material preventing oxide loss at the ILD layers; (d) removing the fin structures, the gate structures and the ILD protection layer above the lower portion of the ILD protection layer; (e) removing the masks of the fin structures and top portions of the gate structures so that top surfaces of the fin structures and top surfaces of the gate structures after the removing are lower than top surfaces of the ILD layers; (f) forming top spacers on the gate structures of which the top portions are removed, and top epitaxial layers on the fin structures of which the masks are removed; and (g) forming a contact structure connected to the top epitaxial layers.

A semiconductor structure includes a substrate, at least one first gate structure, at least one first spacer, at least one source drain structure, at least one conductor, and at least one protection layer. The first gate structure is present on the substrate. The first spacer is present on at least one sidewall of the first gate structure. The source drain structure is present adjacent to the first spacer. The conductor is electrically connected to the source drain structure. The protection layer is present between the conductor and the first spacer and on a top surface of the first gate structure.

An apparatus is provided which comprises: a first region over a substrate, wherein the first region comprises a first semiconductor material having a L-valley transport energy band structure, a second region in contact with the first region at a junction, wherein the second region comprises a second semiconductor material having a X-valley transport energy band structure, wherein a <111> crystal direction of one or more crystals of the first and second semiconductor materials are substantially orthogonal to the junction, and a metal adjacent to the second region, the metal conductively coupled to the first region through the junction. Other embodiments are also disclosed and claimed.

Exemplary semiconductor processing chamber showerheads may include a dielectric plate characterized by a first surface and a second surface opposite the first surface. The dielectric plate may define a plurality of apertures through the dielectric plate. The dielectric plate may define a first annular channel in the first surface of the dielectric plate, and the first annular channel may extend about the plurality of apertures. The dielectric plate may define a second annular channel in the first surface of the dielectric plate. The second annular channel may be formed radially outward from the first annular channel. The showerheads may also include a conductive material embedded within the dielectric plate and extending about the plurality of apertures without being exposed by the apertures. The conductive material may be exposed at the second annular channel.

A method for controlling Schottky barrier height in a semiconductor device includes forming an alloy layer including at least a first element and a second element on a first surface of a semiconductor substrate. The semiconductor substrate is a first element-based semiconductor substrate, and the first element and the second element are Group IV elements. A first thermal anneal of the alloy layer and the first element-based substrate is performed. The first thermal anneal causes the second element in the alloy layer to migrate towards a surface of the alloy layer. A Schottky contact layer is formed on the alloy layer after the first thermal anneal.

A vertical field effect transistor (VFET) device and a method of manufacturing the same are provided. The method includes: (a) providing an intermediate VFET structure comprising a substrate, and fin structures, gate structures and bottom epitaxial layers on the substrate, the gate structures being formed on the fin structures, respectively, each fin structure comprising a fin and a mask thereon, and the bottom epitaxial layers; (b) filling interlayer dielectric (ILD) layers between and at sides of the gate structures; (c) forming an ILD protection layer on the ILD layers, respectively, the ILD protection layer having upper portions and lower portions, and comprising a material preventing oxide loss at the ILD layers; (d) removing the fin structures, the gate structures and the ILD protection layer above the lower portion of the ILD protection layer; (e) removing the masks of the fin structures and top portions of the gate structures so that top surfaces of the fin structures and top surfaces of the gate structures after the removing are lower than top surfaces of the ILD layers; (f) forming top spacers on the gate structures of which the top portions are removed, and top epitaxial layers on the fin structures of which the masks are removed; and (g) forming a contact structure connected to the top epitaxial layers.

A semiconductor device structure and a method for fabricating the semiconductor device structure are disclosed. The method includes receiving a substrate stack including at least one semiconductor fin, the substrate stack including: a bottom source/drain epi region directly below the semiconductor fin; a vertical gate structure directly above the bottom source/drain epi region and in contact with the semiconductor fin; a first inter-layer dielectric in contact with a sidewall of the vertical gate structure; and a second interlayer-layer dielectric directly above and contacting a top surface of the first inter-layer dielectric. The method further including: etching a top region of the semiconductor fin and the gate structure thereby creating a recess directly above the top region of the semiconductor fin and the vertical gate structure; and forming in the recess a top source/drain epi region directly above, and contacting, a top surface of the semiconductor fin.

Techniques for reducing the specific contact resistance of metal-semiconductor (group IV) junctions by interposing a monolayer of group V or group III atoms at the interface between the metal and the semiconductor, or interposing a bi-layer made of one monolayer of each, or interposing multiple such bi-layers. The resulting low specific resistance metal-group IV semiconductor junctions find application as a low resistance electrode in semiconductor devices including electronic devices (e.g., transistors, diodes, etc.) and optoelectronic devices (e.g., lasers, solar cells, photodetectors, etc.) and/or as a metal source and/or drain region (or a portion thereof) in a field effect transistor (FET). The monolayers of group III and group V atoms are predominantly ordered layers of atoms formed on the surface of the group IV semiconductor and chemically bonded to the surface atoms of the group IV semiconductor.