A semiconductor device with different configurations of gate structures and a method of fabricating the same are disclosed. The semiconductor device includes a first gate structure and a second gate structure. The first gate structure includes a first interfacial oxide (IO) layer, a first high-K (HK) dielectric layer disposed on the first interfacial oxide layer, and a first dipole layer disposed at an interface between the first IL layer and the first HK dielectric layer. The HK dielectric layer includes a rare-earth metal dopant or an alkali metal dopant. The second gate structure includes a second IL layer, a second HK dielectric layer disposed on the second IL layer, and a second dipole layer disposed at an interface between the second IL layer and the second HK dielectric layer. The second HK dielectric layer includes a transition metal dopant and the rare-earth metal dopant or the alkali metal dopant.

A method of forming a semiconductor device includes: forming a dummy gate structure over a fin structure that protrudes above a substrate, where the fin structure includes a fin and a layer stack over the fin, where the layer stack comprises alternating layers of a first semiconductor material and a second semiconductor material; forming openings in the fin structure on opposing sides of the dummy gate structure, where the openings exposes first portions of the first semiconductor material and second portions of the second semiconductor material; recessing the exposed first portions of the first semiconductor material to form sidewall recesses in the first semiconductor material; lining the sidewall recesses with a first dielectric material; depositing a second dielectric material in the sidewall recesses on the first dielectric material; after depositing the second dielectric material, annealing the second dielectric material; and after the annealing, forming source/drain regions in the openings.

A semiconductor device includes a first semiconductor well. The semiconductor device includes a channel structure disposed above the first semiconductor well and extending along a first lateral direction. The semiconductor device includes a gate structure extending along a second lateral direction and straddling the channel structure. The semiconductor device includes a first epitaxial structure disposed on a first side of the channel structure. The semiconductor device includes a second epitaxial structure disposed on a second side of the channel structure, the first side and second side opposite to each other in the first lateral direction. The first epitaxial structure is electrically coupled to the first semiconductor well with a second semiconductor well in the first semiconductor well, and the second epitaxial structure is electrically isolated from the first semiconductor well with a dielectric layer.

A method of forming a semiconductor device includes: forming a fin structure protruding above a substrate, where the fin structure includes a fin and a layer stack over the fin, the layer stack comprising alternating layers of a first semiconductor material and a second semiconductor material; forming a first dummy gate structure and a second dummy gate structure over the fin structure; forming an opening in the fin structure between the first dummy gate structure and the second dummy gate structure; converting an upper layer of the fin exposed at a bottom of the opening into a seed layer by performing an implantation process; selectively depositing a dielectric layer over the seed layer at the bottom of the opening; and selectively growing a source/drain material on opposing sidewalls of the second semiconductor material exposed by the opening.

Semiconductor devices including air spacers formed in a backside interconnect structure and methods of forming the same are disclosed. In an embodiment, a device includes a first transistor structure; a front-side interconnect structure on a front-side of the first transistor structure; and a backside interconnect structure on a backside of the first transistor structure, the backside interconnect structure including a first dielectric layer on the backside of the first transistor structure; a first via extending through the first dielectric layer, the first via being electrically coupled to a source/drain region of the first transistor structure; a first conductive line electrically coupled to the first via; and an air spacer adjacent the first conductive line in a direction parallel to a backside surface of the first dielectric layer.

An electrolyte-based field effect transistor includes a dielectric layer; a source electrode and a drain electrode located on top of the dielectric layer; the electrolyte-based transistor further including an electrolyte layer between and on top of the source electrode and the drain electrode, the part of the electrolyte layer located between the source electrode and the drain electrode being in direct contact with the dielectric layer; and a gate electrode on top of the electrolyte layer, the orthogonal projection of the gate electrode in a plane including the source and drain electrodes being located, at least in part, between the source and the drain electrodes.

A method includes forming a semiconductive channel layer on a substrate. A dummy gate is formed on the semiconductive channel layer. Gate spacers are formed on opposite sides of the dummy gate. The dummy gate is removed to form a gate trench between the gate spacers, resulting in the semiconductive channel layer exposed in the gate trench. A semiconductive protection layer is deposited in the gate trench and on the exposed semiconductive channel layer. A top portion of the semiconductive protection layer is oxidized to form an oxidation layer over a remaining portion of the semiconductive protection layer. The oxidation layer is annealed after the top portion of the semiconductive protection layer is oxidized. A gate structure is formed over the semiconductive protection layer and in the gate trench after the oxidation layer is annealed.

A semiconductor device with isolation structures and a method of fabricating the same are disclosed. The method includes forming a fin structure on a substrate forming a superlattice structure with first and second nanostructured layers on the fin structure, forming a source/drain (S/D) opening in the superlattice structure, forming an isolation opening in the fin structure and below the S/D opening, forming a first isolation layer in the isolation opening, selectively forming an oxide layer on sidewalls of the S/D opening, selectively forming an inhibitor layer on the oxide layer, selectively depositing a second isolation layer on the first isolation layer, and forming S/D regions in the S/D opening on the second isolation layer.

Methods and devices including a plurality of memory cells and a first bit line connected to a first column of memory cells of the plurality of memory cells, and a second bit line connected to the first column of cells. The first bit line is shared with a second column of memory cells adjacent to the first column of memory cells. The second bit line is shared with a third column of cells adjacent to the first column of cells opposite the second column of cells.

A forksheet transistor device includes a dual dielectric pillar that includes a first dielectric and a second dielectric that is different from the first dielectric. The dual dielectric pillar physically separates pFET elements from nFET elements. For example, the first dielectric physically separates a pFET gate from a nFET gate while the second dielectric physically separates a pFET source/drain region from a nFET source drain region. When it is advantageous to electrically connect the pFET gate and the nFET gate, the first dielectric may be etched selective to the second dielectric to form a gate connector trench within the dual dielectric pillar. Subsequently, an electrically conductive gate connector strap may be formed within the gate connector trench to electrically connect the pFET gate and the nFET gate.