Abstract: A method for fabricating a vertical transistor device includes forming a first plurality of fins in a first device region and a second plurality of fins in a second device region on a substrate. The first plurality of fins have a SiGe portion exposed above a top surface of the first region and a portion of the second plurality of fins are exposed above a top surface of the second region. The method further includes depositing a first GeO2 layer on the top surface of the device and over the exposed SiGe portion of the first plurality of fins and the exposed portion of the second plurality of fins.

Abstract: Vertical transport field effect transistors (VTFET) are disclosed along with methods of making. The VTFET is made with a novel gate last replacement metal gate (RMG) process. The invention allows uniform and high doping levels without adversely affecting the gate region in the process. The distance from the S/D regions and the junctions are the same. Fin caps protect the fins and gate protecting hard mask protect the dummy gate material during the beginning process steps. The invention enables easy connection and increased surface area at the connection points to reduce contact resistance.

Abstract: A semiconductor structure is provided utilizing a cost effective method in which the vertical gate channel length is substantially the same for vertical field effect transistors (VFETs) that are present in a dense device region and an isolated device region. The VFETs have improved uniformity, device functionality and better yield. No additional lithographic process is used in making such a semiconductor structure.

Abstract: A low forming voltage NVM device is provided by forming a pair of sacrificial conductive pads on an interconnect dielectric material layer that embeds a pair of second electrically conductive structures and a patterned material stack. One of the sacrificial conductive pads has a first area and contacts a surface of one of the second electrically conductive structures that contacts a surface of an underlying first electrically conductive structure, and the other of the sacrificial conductive pads has a second area, different from the first area, and contacts a surface of another of the second electrically conductive structures that contacts a surface of a top electrode of the patterned material stack. A plasma treatment is performed to induce an antenna effect and to convert a dielectric switching material of the patterned material stack into a conductive filament. After plasma treatment, the pair of sacrificial conductive pads is removed.

Abstract: An intermediate semiconductor device structure includes a first area including a memory stack area and a second area including an alignment mark area. The intermediate structure includes a metal interconnect arranged on a substrate in the first area and a first electrode layer arranged on the metal interconnect in the first area, and in the second area. The intermediate structure includes an alignment assisting marker arranged in the second area. The intermediate structure includes a dielectric layer and a second electrode layer arranged on the alignment assisting marker in the second area and on the metal interconnect in the first area. The intermediate structure includes a hard mask layer arranged on the second electrode area. The hard mask layer provides a raised area of topography over the alignment assisting marker. The intermediate structure includes a resist arranged on the hard mask layer in the first area.

Abstract: A method for manufacturing a semiconductor device includes forming a memory element in a dielectric layer. A first conductive layer is deposited on the dielectric layer and the memory element by atomic layer deposition, and a second conductive layer is deposited on the first conductive layer by physical vapor deposition. In the method, the first and second conductive layers are patterned into an electrode on the memory element.

Abstract: A bipolar junction transistor includes a collector having a first surface on a first level and a second surface on a second level. A base is formed on the second level of the collector, and an emitter is formed on the base. A dielectric liner is formed on vertical sidewalls of the collector, the base and the emitter and over the first surface. A conductive region is formed adjacent to the base in the dielectric liner. A base contact is formed along one of the vertical sidewalls to connect to the base through the conductive region.

Abstract: Embodiments of the present invention disclose a method forming a via and a trench. By utilizing a first etching process, a first metal layer of a multi-layered device to form a via, wherein the multi-layered device comprises the first metal layer and a second metal layer, wherein the first metal layer is formed directly on top of the second metal layer, wherein the second metal layer acts as an etch stop for the first etching process, wherein the first etching process does not affect the second metal layer. By utilizing a second etching process, the second metal layer of the multi-layered device to form a trench, wherein first metal layer is not affected by the second etching process, wherein the first etching process and the second etching process are two different etching process.

Abstract: A semiconductor structure, and a method of making the same includes a fin extending upward from a substrate, an epitaxially grown bottom source/drain region in direct contact with the substrate and a bottom portion of the fin. A bottom surface and sidewalls of a metal silicide layer are in direct contact with the epitaxially grown bottom source/drain region. A bottom spacer is located above and in direct contact with the metal silicide layer and a portion of the epitaxially grown bottom source/drain region not covered by the metal silicide layer, the bottom spacer surrounding the fin.

Abstract: Techniques for enhancing VFET performance are provided. In one aspect, a method of forming a VFET device includes: patterning a fin(s) in a substrate; forming bottom source and drains at a base of the fin(s); forming bottom spacers on the bottom source and drains; forming a gate along sidewalls of the fin(s); recessing the gate to expose a top portion of the fin(s); forming an oxide layer along the sidewalls of the top portion of the fin(s); depositing a charged layer over the fin(s) in contact with the oxide layer, wherein the charged layer induces an opposite charge in the top portion of the fin(s) forming a dipole; forming top spacers above the gate; and forming top source and drains above the top spacers. A method of forming a VFET device having both NFETs and PFETs is also provided as are VFET devices formed by the present techniques.

Abstract: A method is presented for reducing heat loss to adjacent semiconductor structures. The method includes forming a plurality of conductive lines within an interlayer dielectric, forming a barrier layer over at least one conductive line of the plurality of conductive lines, forming a via extending to a top surface of the barrier layer, and defining dual air gaps within the via and over the barrier layer.

Abstract: A method of forming a semiconductor structure includes forming a first middle-of-line (MOL) oxide layer and a second MOL oxide layer in the semiconductor structure. The first MOL oxide layer including multiple gate stacks formed on a substrate, and each gate stack of the gate stacks including a source/drain junction. A first nitride layer is formed over a silicide in the first MOL oxide layer. A second nitride layer is formed. Trenches are formed through the second nitride layer down to the source/drain junctions. A nitride cap of the plurality of gate stacks is selectively recessed. At least one self-aligned contact area (CA) element is formed within the first nitride layer. The first MOL oxide layer is selectively recessed. An air-gap oxide layer is deposited. The air gap oxide layer is reduced to the at least one self-aligned CA element and the first nitride layer.

Abstract: A method of forming a semiconductor structure includes forming a metal liner above and in direct contact with a bottom source/drain region, a fin spacer on sidewalls of a fin extending upward from a substrate and a hard mask positioned on top of the fin, the bottom source/drain region includes an epitaxially grown material in direct contact with a bottom portion of the fin not covered by the fin spacer, forming an organic planarization layer directly above the metal liner, simultaneously etching the organic planarization layer and the metal liner until all portions of the metal liner perpendicular to the substrate have been removed and only portions of the metal liner parallel to the substrate remain in contact with the bottom source/drain region, and annealing the semiconductor structure to form a metal silicide layer from the portions of the metal liner in contact with the bottom source/drain region.

Abstract: A semiconductor device includes a gate arranged on a substrate; a source/drain formed on the substrate adjacent to the gate; a source/drain contact extending from the source/drain and through an interlayer dielectric (ILD) over the source/drain, a portion of the source/drain positioned adjacent to the source/drain contact; and a silicide positioned along a sidewall of the source/drain contact between the portion of the source/drain and the source/drain contact, and along an endwall of the source/drain contact between the source/drain contact and the substrate.

Abstract: A semiconductor structure and a method for fabricating the same. The semiconductor structure includes a substrate and a first source/drain layer in contact with at least the substrate. A vertical channel including indium gallium arsenide or germanium contacts at least the first/source drain layer. A gate structure contacts at least the vertical channel. A second source/drain layer contacts at least inner sidewalls of the vertical channel. The method includes epitaxially growing one or more fin structures comprising gallium arsenide in contact with a portion of a substrate. A separate channel layer comprising indium gallium arsenide or germanium is formed in contact with a respective one of the one or more fin structures.

Abstract: Semiconductor structures and methods of forming such structures are disclosed. In an embodiment, the semiconductor structure comprises a substrate, a dielectric layer, and a plurality of gates, including a first gate and a pair of adjacent gates. The method comprises forming gate caps on the adjacent gates, including etching portions of the gate electrodes in the adjacent gates to recess the gate electrodes therein, and forming the caps above the recessed gate electrodes. Conductive metal trenches are formed in the dielectric layer, on the sides of the first gate; and after forming the trenches, a contact is formed over the gate electrode of the first gate and over and on one of the conductive trenches. In embodiments, the contact is a gate contact, and in other embodiments, the contact is a non-gate contact.

Abstract: A phase change material memory device is provided. The phase change material memory device includes one or more electrical contacts in a substrate, and a dielectric cover layer on the electrical contacts and substrate. The phase change material memory device further includes a lower conductive shell in a trench above one of the one or more electrical contacts, and an upper conductive shell on the lower conductive shell in the trench. The phase change material memory device further includes a conductive plug filling the upper conductive shell. The phase change material memory device further includes a liner layer on the dielectric cover layer and conductive plug, and a phase change material block on the liner layer on the dielectric cover layer and in the trench.

Abstract: A low forming voltage NVM device is provided by forming a pair of sacrificial conductive pads on an interconnect dielectric material layer that embeds a pair of second electrically conductive structures and a patterned material stack. One of the sacrificial conductive pads has a first area and contacts a surface of one of the second electrically conductive structures that contacts a surface of an underlying first electrically conductive structure, and the other of the sacrificial conductive pads has a second area, different from the first area, and contacts a surface of another of the second electrically conductive structures that contacts a surface of a top electrode of the patterned material stack. A plasma treatment is performed to induce an antenna effect and to convert a dielectric switching material of the patterned material stack into a conductive filament. After plasma treatment, the pair of sacrificial conductive pads is removed.

Abstract: A vertical vacuum transistor with a sharp tip structure, and associated fabrication process, is provided that is compatible with current vertical CMOS fabrication processing. The resulting vertical vacuum channel transistor advantageously provides improved operational characteristics including a higher operating frequency, a higher power output, and a higher operating temperature while at the same time providing a higher density of vertical transistor devices during the manufacturing process.

Abstract: A method of forming a plurality of vertical fin field effect transistors is provided. The method includes forming a first vertical fin on a first region of a substrate and a second vertical fin on a second region of the substrate, forming an isolation region between the first region and the second region, forming a gate dielectric layer on the vertical fins, forming a first work function layer on the gate dielectric layer, removing an upper portion of the first work function layer from the vertical fin on the first region and the vertical fin on the second region, and forming a second work function layer on the first work function layer and the exposed upper portion of the gate dielectric layer, wherein the first work function layer and second work function layer forms a first combined work function layer with a step in the second work function layer.