A semiconductor device and a method for manufacturing the same, and a NAND memory device are disclosed. The method comprises: forming a substrate that comprises a first active region and an isolation region; forming a first groove between the isolation region and the first channel region, the first groove being partially located in the isolation region, and not penetrating through the isolation region; forming a first gate insulating layer covering the first groove and the first channel region; forming a first gate on the first gate insulating layer, the first gate covering the first channel region and filling the first groove.

An alignment structure for a semiconductor device and a method of forming same are provided. A method includes forming an isolation region over a substrate and forming an alignment structure over the isolation region. Forming the alignment structure includes forming a sacrificial gate electrode layer over the substrate and the isolation region. The sacrificial gate electrode layer is patterned to form a plurality of first sacrificial gates over the isolation region. At least one of the plurality of first sacrificial gates is reshaped. The at least one of the plurality of first sacrificial gates is disposed at an edge of the alignment structure in a plan view. A sidewall of the at least one of the plurality of first sacrificial gates comprises a notch at an interface between the at least one of the plurality of first sacrificial gates and the isolation region.

Exemplary methods of electroplating may include providing a patterned substrate having at least one opening, where the opening includes one or more sidewalls and a bottom surface. The methods may also include plating a first portion of ruthenium-containing material on the bottom surface of the opening at a first deposition rate and a second portion of ruthenium-containing material on the sidewalls of the opening at a second deposition rate, where the first deposition rate is greater than the second deposition rate. The methods may be used to make integrated circuit devices that include void-free, electrically-conductive lines and columns of ruthenium-containing materials.

Exemplary methods of electroplating include contacting a patterned substrate with a plating bath in an electroplating chamber, where the pattern substrate includes at least one opening having a bottom surface and one or more sidewall surfaces. The methods may further include forming a nanotwin-containing metal material in the at least one opening. The metal material may be formed by two or more cycles that include delivering a forward current from a power supply through the plating bath of the electroplating chamber for a first period of time, plating a first amount of the metal on the bottom surface of the opening on the patterned substrate and a second amount of the metal on the sidewall surfaces of the opening, and delivering a reverse current from the power supply through the plating bath of the electroplating chamber to remove some of the metal plated in the opening on the patterned substrate.

Exemplary methods of electroplating may include providing a patterned substrate having at least one opening, where the opening includes one or more sidewalls and a bottom surface. The methods may also include plating a first portion of ruthenium-containing material on the bottom surface of the opening at a first deposition rate and a second portion of ruthenium-containing material on the sidewalls of the opening at a second deposition rate, where the first deposition rate is greater than the second deposition rate. The methods may be used to make integrated circuit devices that include void-free, electrically-conductive lines and columns of ruthenium-containing materials.

A method for forming a semiconductor structure includes providing a semiconductor substrate, forming a sacrificial layer over the semiconductor substrate, etching the sacrificial layer to form a sacrificial pattern, etching the semiconductor substrate using the sacrificial pattern as an etching mask to form an active region of the semiconductor substrate, trimming the sacrificial pattern, and replacing the trimmed sacrificial pattern with a gate electrode.

The present disclosure describes a semiconductor structure and a method for forming the same. The semiconductor structure can include a substrate, an insulating stack formed over the substrate, a vertical structure formed through the insulating stack, a source/drain region formed over the vertical structure, and an isolation structure formed adjacent to the source/drain region and protruding the insulating stack. The source/drain region can include a first side surface and a second side surface. A lateral separation between the first side surface and the vertical structure can be greater than an other lateral separation between the second side surface and the vertical structure.

A semiconductor structure and a method for forming a semiconductor structure are provided. In some embodiments, a method is provided. The method includes following operations. A sacrificial gate structure is formed over a fin structure. The sacrificial gate structure includes a sacrificial gate layer and a sacrificial dielectric layer. The sacrificial gate layer is removed to form a gate trench exposing the sacrificial dielectric layer. A doped region is formed in the fi structure covered by the sacrificial dielectric layer. The sacrificial dielectric layer, a portion of the doped region and a portion of the fin structure are removed from the gate trench. An interfacial layer is formed over the fin structure in the gate trench.

A method of manufacturing a semiconductor device having metal gates and the semiconductor device are disclosed. The method comprises providing a first sacrificial gate associated with a first conductive type transistor and a second sacrificial gate associated with a second conductive type transistor disposed over the substrate, wherein the first conductive type and the second conductive type are complementary; replacing the first sacrificial gate with a first metal gate structure; forming a patterned dielectric layer and/or a patterned photoresist layer to cover the first metal gate structure; and replacing the second sacrificial gate with a second metal gate structure. The method can improve gate height uniformity during twice metal gate chemical mechanical polish processes.

A semiconductor device includes a substrate; a fin structure formed on a substrate; and a gate feature formed over the fin structure, the gate feature comprising a gate dielectric layer, wherein the gate dielectric layer traverses the fin structure to overlay a central portion of the fin structure and opposite side portions of the fin structure that are located in respective undercuts formed in respective portions of a dielectric layer located adjacent to opposite sidewalls of the gate feature, wherein the undercuts extend beyond respective sidewalls of the gate feature and away from the central portion of the fin structure.