Abstract: An integrated circuit includes a stacked FinFET in a second area and a GAA transistor in a first area. The stacked FinFET includes two first source/drain, first and second semiconductor layers alternately stacked one over another and between the two first source/drain, a first gate dielectric layer over top and sidewalls of the first and second semiconductor layers, a first gate electrode layer over the first gate dielectric layer, and first spacer features laterally between the second semiconductor layers and the two first source/drain. The first and the second semiconductor layers include different materials. The GAA transistor includes two second source/drain, third semiconductor layers electrically connecting the two second source/drain, a second gate dielectric layer wrapping around the third semiconductor layers, a second gate electrode over the second gate dielectric layer, and second spacer features laterally between the second gate dielectric layer and the two second source/drain.

Abstract: The present disclosure provides a semiconductor device and a method of forming the same. A semiconductor according one embodiment of the present disclosure include a plurality of channel members disposed over a substrate, a plurality of inner spacer features interleaving the plurality of channel members, a gate structure wrapping around each of the plurality of channel members, and a source/drain feature. The source/drain feature includes a first epitaxial layer in contact with the substrate and the plurality of channel members, and a second epitaxial layer in contact with the first epitaxial layer and the plurality of inner spacer features. The first epitaxial layer and the second epitaxial layer include silicon germanium. A germanium content of the second epitaxial layer is greater than a germanium content of the first epitaxial layer.

Abstract: A semiconductor structure includes an isolation structure; first and second source/drain (S/D) features over the isolation structure, defining a first direction from the first S/D feature to the second S/D feature from a top view; one or more channel layers connecting the first and the second S/D features; a gate structure between the first and the second S/D features and engaging each of the one or more channel layers; and a via structure under the first S/D feature and electrically connecting to the first S/D feature. In a cross-sectional view perpendicular to the first direction, the via structure has a profile that widens and then narrows along a bottom-up direction.

Abstract: Semiconductor devices including backside vias with enlarged backside portions and methods of forming the same are disclosed. In an embodiment, a device includes a first transistor structure in a first device layer; a front-side interconnect structure on a front-side of the first device layer; a first dielectric layer on a backside of the first device layer; a first contact extending through the first dielectric layer to a source/drain region of the first transistor structure; and a backside interconnect structure on a backside of the first dielectric layer and the first contact, the first contact including a first portion having first tapered sidewalls and a second portion having second tapered sidewalls, widths of the first tapered sidewalls narrowing in a direction towards the backside interconnect structure, and widths of the second tapered sidewalls widening in a direction towards the backside interconnect structure.

Abstract: A method includes depositing a dummy semiconductor layer and a first semiconductor layer over a substrate, forming spacers on sidewalls of the dummy semiconductor layer, forming a first epitaxial material in the substrate, exposing the dummy semiconductor layer and the first epitaxial material, where exposing the dummy semiconductor layer and the first epitaxial material includes thinning a backside of the substrate, etching the dummy semiconductor layer to expose the first semiconductor layer, where the spacers remain over and in contact with end portions of the first semiconductor layer while etching the dummy semiconductor layer, etching portions of the first semiconductor layer using the spacers as a mask, and replacing a second epitaxial material and the first epitaxial material with a backside via, the backside via being electrically coupled to a source/drain region of a first transistor.

Abstract: An integrated circuit (IC) structure includes a gate structure, a source epitaxial structure, a drain epitaxial structure, a front-side interconnection structure, a backside dielectric layer, and a backside via. The source epitaxial structure and the drain epitaxial structure are respectively on opposite sides of the gate structure. The front-side interconnection structure is on a front-side of the source epitaxial structure and a front-side of the drain epitaxial structure. The backside dielectric layer is on a backside of the source epitaxial structure and a backside of the drain epitaxial structure and has an air gap therein. The backside via extends through the backside dielectric layer to a first one of the source epitaxial structure and the drain epitaxial structure.

Abstract: A semiconductor device according to the present disclosure includes a channel member including a first connection portion, a second connection portion and a channel portion disposed between the first connection portion and the second connection portion, a first inner spacer feature disposed over and in contact with the first connection portion, a second inner spacer feature disposed under and in contact with the first connection portion, and a gate structure wrapping around the channel portion of the channel member. The channel member further includes a first ridge on a top surface of the channel member and disposed at an interface between the channel portion and the first connection portion. The first ridge partially extends between the first inner spacer feature and the gate structure.

Abstract: Semiconductor device and the manufacturing method thereof are disclosed. An exemplary semiconductor device comprises semiconductor layers over a substrate, wherein the semiconductor layers are stacked up and separated from each other, each semiconductor layer includes a first portion in a first channel region of the substrate and a second portion in a second channel region of the substrate, epitaxial layers formed in a source/drain region between the first channel region and the second channel region, wherein the epitaxial layers are separated from each other and each epitaxial layer is formed between the first portion and the second portion of each semiconductor layer, and a conductive feature wrapping each of the epitaxial layers.

Abstract: A method includes providing a structure having a substrate and a fin. The fin has first and second layers of first and second different semiconductor materials. The first layers and the second layers are alternately stacked over the substrate. The structure further has a sacrificial gate stack engaging a channel region of the fin and gate spacers on sidewalls of the sacrificial gate stack. The method further includes etching a source/drain (S/D) region of the fin, resulting in an S/D trench; partially recessing the second layers exposed in the S/D trench, resulting in a gap between two adjacent layers of the first layers; and depositing a dielectric layer over surfaces of the gate spacers, the first layers, and the second layers. The dielectric layer partially fills the gap, leaving a void sandwiched between the dielectric layer on the two adjacent layers of the first layers.

Abstract: A method includes etching two source/drain regions over a substrate to form two source/drain trenches; epitaxially growing two source/drain features in the two source/drain trenches respectively; performing a cut process to the two source/drain features; and after the cut process, depositing a contact etch stop layer (CESL) over the two source/drain features.

Abstract: A method includes forming first and second fins of a finFET extending above a semiconductor substrate, with a shallow trench isolation (STI) region in between, and a distance between a top surface of the STI region and top surfaces of the first and second fins. First and second fin extensions are provided on top and side surfaces of the first and second fins above the top surface of the STI region. Material is removed from the STI region, to increase the distance between the top surface of the STI region and top surfaces of the first and second fins. A conformal stressor dielectric material is deposited over the fins and STI region. The conformal dielectric stressor material is reflowed, to flow into a space between the first and second fins above a top surface of the STI region, to apply stress to a channel of the finFET.

Abstract: A method includes forming first and second fins of a finFET extending above a semiconductor substrate, with a shallow trench isolation (STI) region in between, and a distance between a top surface of the STI region and top surfaces of the first and second fins. First and second fin extensions are provided on top and side surfaces of the first and second fins above the top surface of the STI region. Material is removed from the STI region, to increase the distance between the top surface of the STI region and top surfaces of the first and second fins. A conformal stressor dielectric material is deposited over the fins and STI region. The conformal dielectric stressor material is reflowed, to flow into a space between the first and second fins above a top surface of the STI region, to apply stress to a channel of the finFET.

Abstract: An anti-roll bar device with a variable rigidity has a first arm assembly having multiple first joining units, a second arm assembly having multiple second joining units, and a variable rigidity unit mounted between the first arm assembly and the second arm assembly and having multiple abutment portions and a variable rigidity coefficient. The first and second joining units are staggered with each other annularly and abut the abutment portions. When a vehicle passes a bumpy terrain, a slight force is exerted on the variable rigidity unit and is absorbed by the variable rigidity unit, such that the vehicle can be kept from tilting and shaking up and down. When the vehicle is in cornering, a larger force is exerted on the variable rigidity unit to increase a rigidity of the variable rigidity unit, such that the variable rigidity unit can transfer torques to keep the vehicle from tilting.

Abstract: An anti-roll bar device with a variable rigidity has a first arm assembly having multiple first joining units, a second arm assembly having multiple second joining units, and a variable rigidity unit mounted between the first arm assembly and the second arm assembly and having multiple abutment portions and a variable rigidity coefficient. The first and second joining units are staggered with each other annularly and abut the abutment portions. When a vehicle passes a bumpy terrain, a slight force is exerted on the variable rigidity unit and is absorbed by the variable rigidity unit, such that the vehicle can be kept from tilting and shaking up and down. When the vehicle is in cornering, a larger force is exerted on the variable rigidity unit to increase a rigidity of the variable rigidity unit, such that the variable rigidity unit can transfer torques to keep the vehicle from tilting.

Abstract: A method includes forming first and second fins of a finFET extending above a semiconductor substrate, with a shallow trench isolation (STI) region in between, and a distance between a top surface of the STI region and top surfaces of the first and second fins. First and second fin extensions are provided on top and side surfaces of the first and second fins above the top surface of the STI region. Material is removed from the STI region, to increase the distance between the top surface of the STI region and top surfaces of the first and second fins. A conformal stressor dielectric material is deposited over the fins and STI region. The conformal dielectric stressor material is reflowed, to flow into a space between the first and second fins above a top surface of the STI region, to apply stress to a channel of the finFET.

Abstract: A method for manufacturing the integrated circuit device including, providing a substrate having a first region and a second region. Forming a dielectric layer over the substrate in the first region and the second region. Forming a sacrificial gate layer over the dielectric layer. Patterning the sacrificial gate layer and the dielectric layer to form gate stacks in the first and second regions. Forming an ILD layer within the gate stacks in the first and second regions. Removing the sacrificial gate layer in the first and second regions. Forming a protector over the dielectric layer in the first region; and thereafter removing the dielectric layer in the second region.

Abstract: A method includes forming first and second fins of a finFET extending above a semiconductor substrate, with a shallow trench isolation (STI) region in between, and a distance between a top surface of the STI region and top surfaces of the first and second fins. First and second fin extensions are provided on top and side surfaces of the first and second fins above the top surface of the STI region. Material is removed from the STI region, to increase the distance between the top surface of the STI region and top surfaces of the first and second fins. A conformal stressor dielectric material is deposited over the fins and STI region. The conformal dielectric stressor material is reflowed, to flow into a space between the first and second fins above a top surface of the STI region, to apply stress to a channel of the finFET.

Abstract: A semiconductor device which includes a first gate structure on a substrate and a second gate structure on the substrate is provided. The semiconductor device further includes an inter-level dielectric (ILD) layer on the substrate between the first gate structure and the second gate structure, wherein a top portion of the ILD layer has a different etch selectivity than a bottom portion of the ILD layer.

Abstract: A method of fabricating a semiconductor device is disclosed. The method includes providing a substrate including an isolation region, forming a resistor over the isolation region, and forming a contact over the resistor. The method also includes implanting with a dopant concentration that is step-increased at a depth of the resistor and that remains substantially constant as depth increases.

Abstract: A method includes forming a first fin and a second fin extending above a semiconductor substrate, with a shallow trench isolation (STI) region between them. A space is defined between the first and second fins above a top surface of the STI region. A first height is defined between the top surface of the STI region and top surfaces of the first and second fins. A flowable dielectric material is deposited into the space. The dielectric material has a top surface above the top surface of the STI region, so as to define a second height between the top surface of the dielectric material and the top surfaces of the first and second fins. The second height is less than the first height. First and second fin extensions are epitaxially formed above the dielectric, on the first and second fins, respectively, after the depositing step.