Abstract: A capacitive wireless power transfer coupler, includes: a coupler transmitting side, including two electrode plates arranged in a same plane, a shielding plate parallel to the electrode plates, and a filling dielectric between each of the electrode plates and the shielding plate; a coupler receiving side, having a same structure as the coupler transmitting side. A side provided with the electrode plates of the coupler transmitting side faces a side provided with the electrode plates of the coupler receiving side, and power transfer is achieved between the two sides through a transfer dielectric, where a relative dielectric constant of the filling dielectric is less than a relative dielectric constant of the transfer dielectric. The issues of increased coupler volume, limited improvement in the capacitive coupling coefficient, and low efficiency of power transfer of the existing capacitive coupler, can be solved.

Abstract: A capacitive coupler with asymmetric insulating layers includes a coupler transmitting side and a coupler receiving side. The coupler transmitting side includes a first insulating cavity, and a first plate and a second plate that are arranged on a first plane. The first insulating cavity is configured to enclose the first plate and the second plate with an insulating material. The coupler receiving side is arranged opposite to the coupler transmitting side and includes a second insulating cavity, a third plate and a fourth plate that are arranged on a second plane. The second insulating cavity is configured to enclose the third plate and the fourth plate with an insulating material. The first insulating cavity and the second insulating cavity have asymmetric insulating layers. The capacitive coupler can improve the power transfer efficiency and reduce the safety distance of the electric field.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed herein. An exemplary semiconductor device comprises a first semiconductor fin and a second semiconductor fin formed over a substrate, wherein lower portions of the first semiconductor fin and the second semiconductor fin are separated by an isolation structure; a first gate stack formed over the first semiconductor fin and a second gate stack formed over the second semiconductor fin; and a separation feature separating the first gate stack and the second gate stack, wherein the separation feature includes a first dielectric layer and a second dielectric layer with an air gap defined therebetween, and a bottom portion of the separation feature being inserted into the isolation structure.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a substrate and a gate stack over the substrate. The semiconductor device structure also includes a spacer element over a sidewall of the gate stack. The spacer element is doped with a dopant, and the dopant contains halide. The spacer element has a first atomic concentration of the dopant near an inner surface of the spacer element adjacent to the gate stack. The spacer element has a second atomic concentration of the dopant near an outer surface of the spacer element. The first atomic concentration of the dopant is different than the second atomic concentration of the dopant.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises first semiconductor stack over a substrate, wherein the first semiconductor stack includes first semiconductor layers separated from each other and stacked up along a direction substantially perpendicular to a top surface of the substrate; second semiconductor stack over the substrate, wherein the second semiconductor stack includes second semiconductor layers separated from each other and stacked up along the direction substantially perpendicular to the top surface of the substrate; inner spacers between edge portions of the first semiconductor layers and between edge portions of the second semiconductor layers; and a bulk source/drain (S/D) feature between the first semiconductor stack and the second semiconductor stack, wherein the bulk S/D feature is separated from the substrate by a first air gap, and the bulk S/D feature is separated from the inner spacers by second air gaps.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises first semiconductor stack over a substrate, wherein the first semiconductor stack includes first semiconductor layers separated from each other and stacked up along a direction substantially perpendicular to a top surface of the substrate; second semiconductor stack over the substrate, wherein the second semiconductor stack includes second semiconductor layers separated from each other and stacked up along the direction substantially perpendicular to the top surface of the substrate; inner spacers between edge portions of the first semiconductor layers and between edge portions of the second semiconductor layers; and a bulk source/drain (S/D) feature between the first semiconductor stack and the second semiconductor stack, wherein the bulk S/D feature is separated from the substrate by a first air gap, and the bulk S/D feature is separated from the inner spacers by second air gaps.

Abstract: A semiconductor structure includes a p-type metal-oxide semiconductor (PMOS) region and an n-type metal-oxide semiconductor (NMOS) region, first source/drain (S/D) features in the PMOS region and second S/D features in the NMOS region, a first channel region connecting the first S/D features and a second channel region connecting the second S/D features, a first high-k metal gate stack (HKMG) over the first channel region and a second HKMG over the second channel region, first gate spacers on sidewalls of the first HKMG and second gate spacers on sidewalls of the second HKMG, a first etch-stop layer (ESL) on the first S/D features and the first gate spacers and a second ESL on the second S/D features and the second gate spacers, an oxide layer on the first ESL but not the second ESL, and an interlayer dielectric (ILD) layer on the oxide layer and the second ESL.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a substrate and a gate stack over the substrate. The semiconductor device structure also includes a spacer element over a sidewall of the gate stack. The spacer element is doped with a dopant, and the dopant reduces a dielectric constant of the spacer element. The spacer element has a first atomic concentration of the dopant near an inner surface of the spacer element adjacent to the gate stack. The spacer element has a second atomic concentration of the dopant near an outer surface of the spacer element. The first atomic concentration of the dopant is different than the second atomic concentration of the dopant.

Abstract: A method includes forming a silicon liner over a semiconductor device, which includes a dummy gate structure disposed over a substrate and S/D features disposed adjacent to the dummy gate structure, where the dummy gate structure traverses a channel region between the S/D features. The method further includes forming an ILD layer over the silicon liner, which includes elemental silicon, introducing a dopant species to the ILD layer, and subsequently removing the dummy gate structure to form a gate trench. Thereafter, the method proceeds to performing a thermal treatment to the doped ILD layer, thereby oxidizing the silicon liner, and forming a metal gate stack in the gate trench and over the oxidized silicon liner.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed herein. An exemplary semiconductor device comprises a first semiconductor fin and a second semiconductor fin formed over a substrate, wherein lower portions of the first semiconductor fin and the second semiconductor fin are separated by an isolation structure; a first gate stack formed over the first semiconductor fin and a second gate stack formed over the second semiconductor fin; and a separation feature separating the first gate stack and the second gate stack, wherein the separation feature includes a first dielectric layer and a second dielectric layer with an air gap defined therebetween, and a bottom portion of the separation feature being inserted into the isolation structure.

Abstract: Interconnects that facilitate reduced capacitance and/or resistance and corresponding techniques for forming the interconnects are disclosed herein. An exemplary interconnect is disposed in an insulating layer. The interconnect has a metal contact, a contact isolation layer surrounding sidewalls of the metal contact, and an air gap disposed between the contact isolation layer and the insulating layer. An air gap seal for the air gap has a first portion disposed over a top surface of the contact isolation layer, but not disposed on a top surface of the insulating layer, and a second portion disposed between the contact isolation layer and the insulating layer, such that the second portion surrounds a top portion of sidewalls of the metal contact. The air gap seal may include amorphous silicon and/or silicon oxide. The contact isolation layer may include silicon nitride. The insulating layer may include silicon oxide.

Abstract: A semiconductor structure includes a substrate, an oxide layer disposed over the substrate, a stack of semiconductor layers disposed over the oxide layer, and an epitaxial source/drain (S/D) feature disposed adjacent to the stack of semiconductor layers. A portion of the epitaxial S/D feature is horizontally surrounded by the oxide layer.

Abstract: Interconnects that facilitate reduced capacitance and/or resistance and corresponding techniques for forming the interconnects are disclosed herein. An exemplary interconnect is disposed in an insulating layer. The interconnect has a metal contact, a contact isolation layer surrounding sidewalls of the metal contact, and an air gap disposed between the contact isolation layer and the insulating layer. An air gap seal for the air gap has a first portion disposed over a top surface of the contact isolation layer, but not disposed on a top surface of the insulating layer, and a second portion disposed between the contact isolation layer and the insulating layer, such that the second portion surrounds a top portion of sidewalls of the metal contact. The air gap seal may include amorphous silicon and/or silicon oxide. The contact isolation layer may include silicon nitride. The insulating layer may include silicon oxide.

Abstract: A method includes forming a semiconductor substrate having an oxide layer embedded therein, forming a multi-layer (ML) stack including alternating channel layers and non-channel layers over the semiconductor substrate, forming a dummy gate stack over the ML, forming an S/D recess in the ML to expose the oxide layer, forming an epitaxial S/D feature in the S/D recess, removing the non-channel layers from the ML to form openings between the channel layers, where the openings are formed adjacent to the epitaxial S/D feature, and forming a high-k metal gate stack (HKMG) in the openings between the channel layers and in place of the dummy gate stack.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises first semiconductor stack over a substrate, wherein the first semiconductor stack includes first semiconductor layers separated from each other and stacked up along a direction substantially perpendicular to a top surface of the substrate; second semiconductor stack over the substrate, wherein the second semiconductor stack includes second semiconductor layers separated from each other and stacked up along the direction substantially perpendicular to the top surface of the substrate; inner spacers between edge portions of the first semiconductor layers and between edge portions of the second semiconductor layers; and a bulk source/drain (S/D) feature between the first semiconductor stack and the second semiconductor stack, wherein the bulk S/D feature is separated from the substrate by a first air gap, and the bulk S/D feature is separated from the inner spacers by second air gaps.

Abstract: A method including providing a device including a gate structure and a source/drain feature adjacent to the gate structure. An insulating layer (e.g., CESL, ILD) is formed over the source/drain feature. A trench is etched in the insulating layer to expose a surface of the source/drain feature. A semiconductor material is then formed in the etched trench on the surface of the source/drain feature. The semiconductor material is converted to a silicide.

Abstract: A semiconductor device structure includes a fin structure formed over a substrate. The structure also includes nanostructures formed over the fin structure. The structure also includes a gate structure wrapped around the nanostructures. The structure also includes a first inner spacer formed beside the gate structure. The structure also includes a second inner spacer formed beside the first inner spacer. The structure also includes spacer layers formed over opposite sides of the gate structure above the nanostructures. The structure also includes source/drain epitaxial structures formed over opposite sides of the fin structure. The second inner spacer is partially embedded in the source/drain epitaxial structures.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises a semiconductor stack including semiconductor layers over a substrate, wherein the semiconductor layers are separated from each other and are stacked up along a direction substantially perpendicular to a top surface of the substrate; an isolation structure around a bottom portion of the semiconductor stack and separating active regions; a metal gate structure over a channel region of the semiconductor stack and wrapping each of the semiconductor layers; a gate spacer over a source/drain (S/D) region of the semiconductor stack and along sidewalls of a top portion of the metal gate structure; and an inner spacer over the S/D region of the semiconductor stack and along sidewalls of lower portions of the metal gate structure and wrapping edge portions of each of the semiconductor layers.

Abstract: A method including providing a device including a gate structure and a source/drain feature adjacent to the gate structure. An insulating layer (e.g., CESL, ILD) is formed over the source/drain feature. A trench is etched in the insulating layer to expose a surface of the source/drain feature. A semiconductor material is then formed in the etched trench on the surface of the source/drain feature. The semiconductor material is converted to a silicide.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises first semiconductor stack over a substrate, wherein the first semiconductor stack includes first semiconductor layers separated from each other and stacked up along a direction substantially perpendicular to a top surface of the substrate; second semiconductor stack over the substrate, wherein the second semiconductor stack includes second semiconductor layers separated from each other and stacked up along the direction substantially perpendicular to the top surface of the substrate; inner spacers between edge portions of the first semiconductor layers and between edge portions of the second semiconductor layers; and a bulk source/drain (S/D) feature between the first semiconductor stack and the second semiconductor stack, wherein the bulk S/D feature is separated from the substrate by a first air gap, and the bulk S/D feature is separated from the inner spacers by second air gaps.