Semiconductor devices and methods of manufacturing the same are described. The method includes forming a bottom dielectric isolation (BDI) layer on a substrate and depositing a template material in the source/drain trench. The template material is crystallized. Epitaxially growth of the source and drain regions then proceeds, which growth advantageously occurring on the bottom and sidewalls of the source and drain regions.

A semiconductor structure and a forming method thereof are provided. The forming method of the semiconductor structure comprises: providing a substrate comprising a first area for forming a P-channel Metal Oxide Semiconductor (PMOS) transistor and a second area for forming an N-channel Metal Oxide Semiconductor (NMOS) transistor; forming a channel layer on the surface of the first area of the substrate; adjusting the oxidation rate of the channel layer to reduce the difference between the oxidation rate of the channel layer and the oxidation rate of the substrate; and oxidizing the surfaces of the channel layer and the second area of the substrate to form a first transition oxide layer covering the surface of the channel layer and a second transition oxide layer covering the surface of the second area of the substrate.

Particular embodiments described herein provide for an electronic device that can include a nanowire channel. The nanowire channel can include nanowires and the nanowires can be about fifteen (15) or less angstroms apart. The nanowire channel can include more than ten (10) nanowires and can be created from a MXene material.

A crystalline channel layer of a semiconductor material is formed in a backend process over a crystalline dielectric seed layer. A crystalline magnesium oxide MgO is formed over an amorphous inter-layer dielectric layer. The crystalline MgO provides physical link to the formation of a crystalline semiconductor layer thereover.

A semiconductor memory device comprises: a laterally oriented hybrid channel including outer channel materials and an inner channel material interposed between the outer channel materials; a laterally oriented double word line with the hybrid channel interposed therebetween; a vertically oriented bit line connected to a first end of the hybrid channel; and a capacitor connected to a second end of the hybrid channel.

Disclosed are semiconductor devices and their fabrication methods. The semiconductor device comprises a logic cell on a substrate, and a first metal layer on the logic cell. The first metal layer includes first and second power lines and first to third lower lines on first to third wiring tracks therebetween. The first to third wiring tracks extend in parallel in the first direction. The first lower line includes first and second lines spaced apart in the first direction from each other at a first distance. The third lower line includes third and fourth lines spaced apart in the first direction at a second distance. The first line has a first end facing the second line. The third line has a second end facing the fourth line. A curvature at the first end is substantially the same as that at the second end.

Semiconductor devices and methods of manufacturing the same are described. Transistors are fabricated using a standard process flow. A via opening extending from the top surface of the substrate to a bottom surface of the wafer device is formed, thus allowing nano TSV for high density packaging, as well as connecting the device to the backside power rail. A metal is deposited in the via opening, and the bottom surface of the wafer device is bound to a bonding wafer. The substrate is optionally thinned, and a contact electrically connected to the metal is formed.

A method for making a semiconductor device may include forming an inverted T channel on a substrate, with the inverted T channel comprising a superlattice. The superlattice may include a plurality of stacked groups of layers, with each group of layers comprising a plurality of stacked base semiconductor monolayers defining a base semiconductor portion, and at least one non-semiconductor monolayer constrained within a crystal lattice of adjacent base semiconductor portions. The method may further include forming source and drain regions on opposing ends of the inverted T channel, and forming a gate overlying the inverted T channel between the source and drain.

A semiconductor device includes a substrate that includes an active pattern, a channel pattern disposed on the active pattern, where the channel pattern includes a plurality of semiconductor patterns that are vertically stacked and spaced apart from each other, a source/drain pattern connected to the semiconductor patterns, and a gate electrode disposed on the semiconductor patterns. The gate electrode includes a plurality of portions that are respectively interposed between the semiconductor patterns, and the source/drain pattern includes a buffer layer in contact with the semiconductor patterns and a main layer disposed on the buffer layer. The buffer layer contains silicon germanium (SiGe) and includes a first semiconductor layer and a first reflow layer thereon. A germanium concentration of the first reflow layer is less than that of the first semiconductor layer.

Techniques are provided herein to form semiconductor devices having strained channel regions. In an example, semiconductor nanoribbons of silicon germanium (SiGe) or germanium tin (GeSn) may be formed and subsequently annealed to drive the germanium or tin inwards along a portion of the semiconductor nanoribbons thus increasing the germanium or tin concentration through a central portion along the lengths of the one or more nanoribbons. Specifically, a nanoribbon may have a first region at one end of the nanoribbon having a first germanium concentration, a second region at the other end of the nanoribbon having substantially the same first germanium concentration (e.g., within 5%), and a third region between the first and second regions having a second germanium concentration higher than the first concentration. A similar material gradient may also be created using tin. The change in material composition (gradient) along the nanoribbon length imparts a compressive strain.