Abstract: A method of fabricating a semiconductor device includes providing a dummy structure including channel layers disposed over a frontside of a substrate, inner spacers disposed between adjacent channels of the channel layers and at lateral ends of the channel layers, and a gate structure interposing the plurality of channel layers. The dummy structure is disposed at an active edge adjacent to an active region. Perform an etching process to etch the gate structure and the plurality of channel layers to form a cut region along the active edge. Deposit a conductive material in the cut region to form a conductive feature. The method further includes thinning the substrate from a backside of the substrate to expose the conductive feature and forming a backside metal wiring layer on the backside of the substrate. The backside metal wiring layer is in electrical connection with the conductive feature.

Abstract: Provided is a construction method for a fully prefabricated multi-story concrete plant, the construction method may achieve full coverage of a hoisting operation of the large beam and column prefabricated components of a floor by employing a single intelligent hoisting robot, an angle change of the track devices, an angle change of a moving device, and a self-lifting device. It is not necessary to arrange a transition track at the turn of the installation route, which saves space and installation cost, and overcomes the disadvantage of high cost caused by the traditional prefabricated construction mode of multi-story concrete plant, which needs to arrange a plurality of large hoisting equipment. It may achieve the mechanization and intelligence of the whole construction process of the fully prefabricated multi-story concrete plant.

Abstract: Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes a plurality of nanostructures surrounded by a gate structure, and a source/drain (S/D) structure adjacent to the gate structure. The semiconductor structure includes a first S/D contact structure formed over a first side of the S/D structure, and a second S/D contact structure formed over a second side of the S/D structure. The second S/D contact structure includes a conductive layer. The semiconductor structure includes a dielectric layer adjacent to the second contact structure, and the dielectric layer is doped with germanium (Ge), and the dielectric layer is in direct contact with the conductive layer.

Abstract: A device includes a channel layer, a gate structure, a first source/drain epitaxial structure, a second source/drain epitaxial structure, a front-side interconnection structure, and a backside via. The gate structure is across the channel layer. The first source/drain epitaxial structure and the second source/drain epitaxial structure are on opposite sides of the gate structure and are connected to the channel layer. The front-side interconnection structure is on a front-side of the first source/drain epitaxial structure. The backside via is connected to a backside of the first source/drain epitaxial structure. A backside surface of the first source/drain epitaxial structure is at a height between a height of a backside surface of the backside via and a height of a backside surface of the gate structure.

Abstract: A semiconductor structure includes a semiconductor substrate, a metallization feature over the semiconductor substrate, a first dielectric feature, a second dielectric feature, and a via contact. The metallization feature includes a first bottom corner and a second bottom corner opposite to the first bottom corner. The first dielectric feature is adjacent to the first bottom corner, and the second dielectric feature is adjacent to the second bottom corner. The metallization feature is interposed between the first dielectric feature and the second dielectric feature. In some embodiments, an included angle of the first bottom corner defined by a sidewall of first dielectric feature and a bottom surface of the metallization feature is less than 90°. The via contact is configured to connect the metallization feature to the semiconductor substrate.

Abstract: A method is provided for forming a metal contact plug. In one step, a substrate, which is an Si substrate or an SiO2 substrate, is etched to form a contact hole. In one step, a dielectric liner layer is formed on a sidewall of the contact hole. In one step, the metal contact plug that is in contact with the dielectric liner layer is formed in the contact hole. In one step, an implantation process is performed on the substrate, so as to implant dopants having an atomic size greater than that of Si into the substrate.

Abstract: A semiconductor device includes a plurality of stacks that each includes a plurality of nanostructures stacked over each other, a gate structure wrapping around the nanostructures and extending between the stacks, source and drain structures, and a plurality of fin structures respectively disposed on the stacks. A first surface of the gate structure between the stacks is substantially coplanar with first surfaces of the fin structures facing to the nanostructures or between the first surfaces of the fin structures and the nanostructures.

Abstract: In some embodiments, the present disclosure relates to a method of forming an integrated chip. The method includes forming a gate electrode over a substrate. The gate electrode is laterally separated from a dielectric by a spacer structure. A sacrificial layer is formed over a top surface of the gate electrode. A liner layer is formed along a sidewall of the spacer structure and on the sacrificial layer. The sacrificial layer is removed and a hard mask material is formed over the gate electrode. A part of the dielectric is removed to form a contact opening laterally separated from the gate electrode by the spacer structure. A conductive contact is formed within the contact opening.

Abstract: In some embodiments, the present disclosure relates to a method that includes forming a dielectric layer over a substrate and patterning the dielectric to form an opening in the dielectric layer. Further, a conductive material is formed within the opening of the dielectric layer. A planarization process is performed to remove portions of the conductive material arranged over the dielectric layer thereby forming a conductive feature within the opening of the dielectric layer. An anti-oxidation layer is formed on upper surfaces of the conductive feature, and then, the anti-oxidation layer is removed.

Abstract: An IC structure includes a first transistor, first gate spacers, a second transistor, second gate spacers, a backside metal line, and a metal contact. The first transistor includes first source/drain regions and a first gate structure between the first source/drain regions. The first gate spacers space apart the first source/drain regions from the first gate structure. The second transistor comprises second source/drain regions and a second gate structure between the second source/drain regions. The second gate spacers space apart the second source/drain regions from the second gate structure. The first gate spacers and the second gate spacers extend along a first direction. The backside metal line extends between the first transistor and the second transistor along a second direction. The first metal contact wraps around one of the second source/drain regions and has a protrusion interfacing the backside metal line.

Abstract: A method provides a structure having a fin oriented lengthwise and widthwise along first and second directions respectively, an isolation structure adjacent to sidewalls of the fin, and first and second source/drain (S/D) features over the fin. The method includes forming an etch mask exposing a first portion of the fin under the first S/D feature and covering a second portion of the fin under the second S/D feature; removing the first portion of the fin, resulting in a first trench; forming a first dielectric feature in the first trench; and removing the second portion of the fin to form a second trench. The first dielectric feature and the isolation structure form first and second sidewalls of the second trench respectively. The method includes laterally etching the second sidewalls, thereby expanding the second trench along the second direction and forming a via structure in the expanded second trench.

Abstract: Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes nanostructures over a substrate, and a gate structure surrounding the nanostructures. The gate structure includes gate dielectric layers and gate electrode layers. The semiconductor structure also includes a source/drain (S/D) structure adjacent to the gate structure, and an inner spacer layer between the gate structure and the S/D structure. The semiconductor structure further includes a filling layer over the gate structure, and the filling layer has a protrusion portion embedded in a space, the space is surrounded by the inner spacer, the gate dielectric layer and the gate electrode layer. The semiconductor structure also includes a first S/D contact structure formed over the filling layer.

Abstract: A method for forming a semiconductor device structure includes forming a gate structure surrounding the nanostructures. The method also includes forming source/drain structures over opposite sides of the gate structure. The method also includes forming a trench beside the source/drain structures. The method also includes depositing a first liner layer in the trench. The method also includes depositing a dummy material layer over the first liner layer. The method also includes etching the dummy material layer. The method also includes depositing a second liner layer over the dummy material layer. The method also includes forming a power via structure in the trench. The method also includes removing the dummy material layer to form an opening between the first liner layer and the second liner layer. The method also includes forming a sealing layer over the opening. An air spacer is formed under the sealing layer.

Abstract: Methods of forming through vias for providing connections between a front-side of a substrate and a backside of the substrate and semiconductor devices including the same are disclosed. In an embodiment, a semiconductor device includes a gate structure on a substrate; a first isolation feature extending partially through the gate structure; a first conductive feature extending through the first isolation feature; and a second conductive feature extending partially through the gate structure, the second conductive feature being electrically coupled to the first conductive feature.

Abstract: A method having a semiconductor substrate received and a first dielectric layer is formed over the semiconductor substrate. A trench is formed in the first dielectric layer. The trench is filled to form a conductive layer in the first dielectric layer. The conductive layer is segmented to form a first conductive feature and a second conductive feature separated from each other by a recess. The recess is filled with a second dielectric layer, such that one or both of the conductive features are end-capped by a portion of the first dielectric layer and a portion of the second dielectric layer.

Abstract: A semiconductor structure includes first and second epitaxial features, at least one semiconductor channel layer connecting the first and second epitaxial features, and a gate structure engaging the semiconductor channel layer. The first and second epitaxial features, the semiconductor channel layer, and the gate structure are at a frontside of the semiconductor structure. The semiconductor structure also includes a backside metal wiring layer at a backside of the semiconductor structure, and a backside conductive contact electrically connecting the first epitaxial feature to the backside metal wiring layer. The backside metal wiring layer is spaced away from the gate structure with an air gap therebetween.

Abstract: A method is provided for forming a contact plug by bottom-up metal growth. In one step, a substrate is etched to form a contact hole that exposes a silicon-containing feature in the substrate. In one step, a silicide layer is formed on the silicon-containing feature. In one step, a metal seed layer is formed over the silicide layer. In one step, a metal contact layer is deposited over the metal seed layer to form the contact plug in the contact hole.

Abstract: Semiconductor structures and methods for manufacturing the same are provided. The semiconductor structure includes first nanostructures surrounded by a first gate structure, and a first source/drain (S/D) structure adjacent to the first gate structure. The semiconductor structure includes a first contact structure formed over a first side of the first S/D structure, and a second contact structure formed over a second side of the first S/D structure. The second contact structure includes a first portion and a second portion. The first portion and the second portion are made of different materials. The first S/D structure has a first width. The second portion has a second width. The first width is smaller than the second width.

Abstract: A semiconductor structure includes an epitaxial region having a front side and a backside. The semiconductor structure includes an amorphous layer formed over the backside of the epitaxial region, wherein the amorphous layer includes silicon. The semiconductor structure includes a first silicide layer formed over the amorphous layer. The semiconductor structure includes a first metal contact formed over the first silicide layer.

Abstract: A semiconductor structure includes a power rail; an isolation structure over the power rail; 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; one or more channel layers over the isolation structure and connecting the first and the second S/D features; a first via structure extending through the isolation structure and electrically connecting the first S/D feature and the power rail; and a first dielectric feature extending through the isolation structure and physically contacting the second S/D feature and the power rail. The first via structure has a first width in a first cross-section perpendicular to the first direction, the first dielectric feature has a second width in a second cross-section parallel to the first cross-section, and the first width is greater than the second width.