Abstract: Provided is a semiconductor device including a substrate, one hybrid fin, a gate, and a dielectric structure. The substrate includes at least two fins. The hybrid fin is disposed between the at least two fins. The gate covers portions of the at least two fins and the hybrid fin. The dielectric structure lands on the hybrid fin to divide the gate into two segment. The two segments are electrically isolated to each other by the dielectric structure and the hybrid fin. The hybrid fin includes a first portion, disposed between the two segments of the gate; and a second portion, disposed aside the first portion, wherein a top surface of the second portion is lower than a top surface of the first portion.

Abstract: A method of applying and then removing a protective layer over a portion of a gate stack is provided. The protective layer is deposited and then a plasma precursor is separated into components. Neutral radicals are then utilized in order to remove the protective layer. In some embodiments the removal also forms a protective by-product which helps to protect underlying layers from damage during the etching process.

Abstract: A method includes forming a semiconductor fin over a substrate; forming a gate structure over the semiconductor fin, the gate structure comprising: a first metallic layer; a second metallic layer over the first metallic layer, wherein the first metallic layer is a metal compound of a first element and a second element and the second metallic layer is a single-element metal of the second element; and an oxide layer between the first metallic layer and the second metallic layer.

Abstract: The disclosure provides a pattern collapse free wet clean process for fabricating semiconductor devices. By performing post reactive ion etching (RIE) using a fluorine-containing gas such as C2F6, followed by cleaning in a single wafer cleaner (SWC) with diluted hydrofluoric acid (HF) or in a solution of ammonia and HF, a substrate with multiple pattern collapse free high aspect ratio shallow trench isolation (STI) features can be obtained.

Abstract: Structures and formation methods of a chip package are provided. The chip package includes a semiconductor die having a conductive element and an antenna element over the semiconductor die. The chip package also includes a first conductive feature electrically connecting the conductive element of the semiconductor die and the antenna element. The chip package further includes a protective layer surrounding the first conductive feature. In addition, the chip package includes a second conductive feature over the first conductive feature. A portion of the second conductive feature is between the first conductive feature and the protective layer.

Abstract: A method of manufacturing a semiconductor package includes depositing a first dielectric layer over a carrier substrate. A first metallization pattern is formed over the first dielectric layer. The first metallization pattern has a first opening exposing the first dielectric layer. A second dielectric layer is deposited over the first metallization pattern, forming a dielectric slot through the first metallization pattern by filling the first opening. A second metallization pattern and a third dielectric layer are formed over the second dielectric layer. A through via is formed over the third dielectric layer, so that the dielectric slot is laterally under the through via.

Abstract: A thin-film transistor includes a substrate, a first thin-film structure, a gate structure, and a second thin-film structure that are sequentially disposed on one another. The first thin-film structure includes a channel layer, and first source and drain layers disposed at opposite sides of the channel layer. The gate structure includes a common gate electrode disposed on the channel layer, and a gate insulating layer wrapping the common gate electrode and covering the first thin-film structure. The second thin-film structure includes an active layer disposed on the gate insulating layer and including an indium oxide-based material, and second source and drain layers disposed at opposite sides of the active layer.

Abstract: A semiconductor device includes a substrate comprising a semiconductor fin, a gate structure over the semiconductor fin, and source/drain structures over the semiconductor fin and on opposite sides of the gate structure. The gate stack comprises a high-k dielectric layer; a first work function metal layer over the high-k dielectric layer; an oxide of the first work function metal layer over the first work function metal layer; and a second work function metal layer over the oxide of the first work function metal layer, in which the first and second work function metal layers have different compositions; and a gate electrode over the second work function metal layer.

Abstract: A method of applying and then removing a protective layer over a portion of a gate stack is provided. The protective layer is deposited and then a plasma precursor is separated into components. Neutral radicals are then utilized in order to remove the protective layer. In some embodiments the removal also forms a protective by-product which helps to protect underlying layers from damage during the etching process.

Abstract: A first dielectric layer is formed over upper and side surfaces of a semiconductor fin structure. A mask layer is formed over a first portion of the first dielectric layer disposed over the upper surface of the fin structure. The mask layer and the first dielectric layer have different material compositions. Second portions of the first dielectric layer disposed on side surfaces of the fin structure are etched. The mask layer protects the first portion of the first dielectric layer from being etched. A second dielectric layer is formed over the mask layer and the side surfaces of the fin structure. An oxidation process is performed to convert the mask layer into a dielectric material having substantially a same material composition as the first or second dielectric layer. The dielectric material and remaining portions of the first or second dielectric layer collectively serve as a gate dielectric of a transistor.

Abstract: A semiconductor device includes a silicon substrate and a fin formed above the substrate. The fin provides active regions for two devices, such as gate-all-around transistors. The semiconductor device also includes a fin-insulating structure positioned to electrically isolate the active regions for the two devices. The fin-insulating structure is formed in a trench, with a first portion adjacent the fin and a second portion below the fin and extending into the substrate. The fin-insulating structure includes an oxide liner in the second portion of the trench, but not the first portion. The fin-insulating structure is further filled with an insulating material such as silicon nitride.

Abstract: A method of forming a semiconductor device structure is provided. The method includes forming semiconductor fins at a first conductivity type region and a second conductivity type region of a substrate, forming a sacrificial gate structure across a portion of the semiconductor fins, wherein the sacrificial gate structure comprises a sacrificial gate dielectric layer and a sacrificial gate electrode layer over the sacrificial gate dielectric layer, and the sacrificial gate dielectric layer on the semiconductor fins of the first conductivity type region is asymmetrical in thickness between a top and a sidewall of the semiconductor fins. The method also includes forming a gate spacer on opposite sidewalls of the sacrificial gate structure, recessing the semiconductor fins not covered by the sacrificial gate structure and the gate spacer, forming source/drain feature on the recessed semiconductor fins, and removing the sacrificial gate structure to expose the top of the semiconductor fins.

Abstract: A manufacturing method of a semiconductor package includes the following steps. Semiconductor chips are disposed on a carrier. The semiconductor chips are grouped in a plurality of package units. The semiconductor chips are encapsulated in an encapsulant to form a reconstructed wafer. A redistribution structure is formed on the encapsulant. The redistribution structure electrically connects the semiconductor chips within a same package unit of the plurality of package units. The individual package units are separated by cutting through the reconstructed wafer along scribe line regions. In the reconstructed wafer, the plurality of package units are arranged so as to balance the number of scribe line regions extending across opposite halves of the reconstructed wafer in a first direction with respect to the number of scribe line regions extending across opposite halves of the reconstructed wafer in a second direction perpendicular to the first direction.

Abstract: In one exemplary aspect, a method for semiconductor manufacturing comprises forming first and second silicon nitride features on sidewall surfaces of a contact hole, where the contact hole is disposed in a dielectric layer and above a source/drain (S/D) feature. The method further comprises forming a contact plug in the contact hole, the contact plug being electrically coupled to the S/D feature, removing a top portion of the contact plug to create a recess in the contact hole, forming a hard mask layer in the recess, and removing the first and second silicon nitride features via selective etching to form first and second air gaps, respectively.

Abstract: A first dielectric layer is formed over upper and side surfaces of a semiconductor fin structure. A mask layer is formed over a first portion of the first dielectric layer disposed over the upper surface of the fin structure. The mask layer and the first dielectric layer have different material compositions. Second portions of the first dielectric layer disposed on side surfaces of the fin structure are etched. The mask layer protects the first portion of the first dielectric layer from being etched. A second dielectric layer is formed over the mask layer and the side surfaces of the fin structure. An oxidation process is performed to convert the mask layer into a dielectric material having substantially a same material composition as the first or second dielectric layer. The dielectric material and remaining portions of the first or second dielectric layer collectively serve as a gate dielectric of a transistor.

Abstract: A package structure includes a semiconductor die, an insulating encapsulant, a first redistribution layer, a second redistribution layer, a heat dissipation element and conductive balls. The insulating encapsulant is encapsulating the semiconductor die, and has a first surface and a second surface opposite to the first surface. The first redistribution layer is located on the first surface of the insulating encapsulant and includes at least one feed line and one ground plate. The second redistribution layer is located on the second surface of the insulating encapsulant and electrically connected to the semiconductor die and the first redistribution layer. The heat dissipation element is disposed on the first redistribution layer and includes a conductive base and antenna patterns, wherein the antenna patterns is electrically connected to the feed line and is electrically coupled to the ground plate of the first redistribution layer.

Abstract: The disclosure provides a pattern collapse free wet clean process for fabricating semiconductor devices. By performing post reactive ion etching (RIE) using a fluorine-containing gas such as C2F6, followed by cleaning in a single wafer cleaner (SWC) with diluted hydrofluoric acid (HF) or in a solution of ammonia and HF, a substrate with multiple pattern collapse free high aspect ratio shallow trench isolation (STI) features can be obtained.

Abstract: In one exemplary aspect, a method for semiconductor manufacturing comprises forming first and second silicon nitride features on sidewall surfaces of a contact hole, where the contact hole is disposed in a dielectric layer and above a source/drain (S/D) feature. The method further comprises forming a contact plug in the contact hole, the contact plug being electrically coupled to the S/D feature, removing a top portion of the contact plug to create a recess in the contact hole, forming a hard mask layer in the recess, and removing the first and second silicon nitride features via selective etching to form first and second air gaps, respectively.

Abstract: A dummy fin described herein includes a low dielectric constant (low-k or LK) material outer shell. A leakage path that would otherwise occur due to a void being formed in the low-k material outer shell is filled with a high dielectric constant (high-k or HK) material inner core. This increases the effectiveness of the dummy fin to provide electrical isolation and increases device performance of a semiconductor device in which the dummy fin is included. Moreover, the dummy fin described herein may not suffer from bending issues experienced in other types of dummy fins, which may otherwise cause high-k induced alternating current (AC) performance degradation. The processes for forming the dummy fins described herein are compatible with other fin field effect transistor (finFET) formation processes and are be easily integrated to minimize and/or prevent polishing issues, etch back issues, and/or other types of semiconductor processing issues.

Abstract: A package structure includes a semiconductor die, an insulating encapsulant, a first redistribution layer, a second redistribution layer, a heat dissipation element and conductive balls. The insulating encapsulant is encapsulating the semiconductor die, and has a first surface and a second surface opposite to the first surface. The first redistribution layer is located on the first surface of the insulating encapsulant and includes at least one feed line and one ground plate. The second redistribution layer is located on the second surface of the insulating encapsulant and electrically connected to the semiconductor die and the first redistribution layer. The heat dissipation element is disposed on the first redistribution layer and includes a conductive base and antenna patterns, wherein the antenna patterns is electrically connected to the feed line and is electrically coupled to the ground plate of the first redistribution layer.