The present disclosure provides a semiconductor processing apparatus according to one embodiment. The semiconductor processing apparatus includes a chamber; a base station located in the chamber for supporting a semiconductor substrate; a preheating assembly surrounding the base station; a first heating element fixed relative to the base station and configured to direct heat to the semiconductor substrate; and a second heating element moveable relative to the base station and operable to direct heat to a portion of the semiconductor substrate.

A semiconductor device according to the present disclosure includes a gate-all-around (GAA) transistor in a first device area and a fin-type field effect transistor (FinFET) in a second device area. The GAA transistor includes a plurality of vertically stacked channel members and a first gate structure over and around the plurality of vertically stacked channel members. The FinFET includes a fin-shaped channel member and a second gate structure over the fin-shaped channel member. The fin-shaped channel member includes semiconductor layers interleaved by sacrificial layers.

A method for fabricating a semiconductor device includes the steps of forming a gate structure on a substrate, forming recesses adjacent to two sides of the gate structure, forming a buffer layer in the recesses, forming a first linear bulk layer on the buffer layer, forming a second linear bulk layer on the first linear bulk layer, forming a bulk layer on the second linear bulk layer, and forming a cap layer on the bulk layer.

A semiconductor device includes a fin structure that protrudes vertically out of a substrate, wherein the fin structure contains silicon germanium (SiGe). An epi-silicon layer is disposed on a sidewall of the fin structure. The epi-silicon layer contains nitrogen. One or more dielectric liner layers are disposed on the epi-silicon layer. A dielectric isolation structure is disposed over the one or more dielectric liner layers.

An integrated circuit device includes a transistor, a conductive contact plug, a first interconnect structure, and a conductive structure. The transistor includes a gate structure and source/drain regions at opposite sides of the gate structure. The conductive contact plug is electrically coupled to one of the gate structure and the source/drain regions. The first interconnect structure is disposed over the conductive contact plug. The conductive structure is disposed electrically coupled to the conductive contact plug by the first interconnect structure. The conductive structure includes a fill metal and a transition metal dichalcogenide liner cupping an underside of the fill metal. A bottommost position of the transition metal dichalcogenide liner is lower than a bottommost position of the fill metal.

A method for producing a power semiconductor device with heat dissipating capability includes epitaxially growing a GaN-based buffer layer on a first surface of a sapphire substrate, epitaxially growing a Ga.sub.2O.sub.3 semiconductor layer on the GaN-based buffer layer, forming a source and a drain, a gate dielectric layer, a first gate, an insulator layer, and a metal adhesive layer in sequence, removing part of the metal adhesive layer, the insulator layer, and the gate dielectric layer to expose one of the source and the drain, forming a heat sink which covers the metal adhesive layer, the insulator layer, the gate dielectric layer, and the one of the source and the drain, and conducting a laser lift-off process through a second surface of the sapphire substrate to remove the sapphire substrate and the GaN-based buffer layer.

A method for making a semiconductor device may include forming a superlattice gettering layer on a substrate. 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 also include forming a memory device above the superlattice gettering layer including a metal induced crystallization (MIC) channel adjacent the semiconductor substrate, and a gate associated with the MIC channel. The superlattice gettering layer may further include gettered metal particles from the MIC channel.

Disclosed are a semiconductor structure and a method for manufacturing a semiconductor structure, the method includes: forming a first transition layer, a protection layer and an active structure layer sequentially epitaxially on a side of a growth substrate, where a surface, away from the growth substrate, of the first transition layer is a two-dimensional flat surface; on a first plane, an orthographic projection of the active structure layer is at least partially covered by an orthographic projection of the protection layer, and the first plane is perpendicular to an arrangement direction of the protection layer and the active structure layer; detaching the growth substrate by a laser lift-off process, to make the epitaxial layer transferred to a transfer substrate; etching the first transition layer up to the protection layer, to make a surface, away from the active structure layer, of the protection layer to be a planarization surface.

A manufacturing method of a nitride semiconductor device includes: introducing a p type impurity into at least a part of an upper layer portion of a first nitride semiconductor layer to form a p type impurity introduction region; forming a second nitride semiconductor layer from an upper surface of the first nitride semiconductor layer so as to include the p type impurity introduction region; and performing an anneal treatment in a state where the second nitride semiconductor layer is formed on the first nitride semiconductor layer.

A FET channel includes a stack of silicon nanosheets. The silicon nanosheets are oriented parallel to a planar portion of the FET in which the FET channel is formed. The FET channel also includes a vertical blocker fin. The vertical blocker fin is attached to at least one nanosheet in the stack of nanosheets.