An integrated circuit structure includes a metal line that has an upper surface defining a periphery; a dielectric spacer that is formed around the periphery of the upper surface of the metal line; and a metal via that contacts the metal line and the dielectric spacer adjacent to the periphery of the upper surface. A method for making a semiconductor structure includes depositing a spacer around the periphery of an upper surface of a metal line; and depositing a via onto the metal line, so that a part of the via overlaps the spacer.

A semiconductor device includes bit lines, gate electrodes, a gate insulation pattern and a channel structure on a substrate. Each of the bit lines extends in a first direction, and the bit lines may be spaced apart from each other in a second direction. The gate electrodes are spaced apart from each other in the first direction, and each of the gate electrodes extends in the second direction. For each of the gate electrodes, a gate insulation pattern is formed on a sidewall in the first direction of the gate electrode, and a channel structure is formed on a sidewall in the first direction of the gate insulation pattern. The channel structure includes a first amorphous channel including an amorphous oxide semiconductor and a first crystalline channel including a crystalline oxide semiconductor and contacting an upper surface of the first amorphous channel.

The present disclosure provides a semiconductor structure, including: a semiconductor device layer including a first surface and a second surface, wherein the first surface is at a front side of the semiconductor device layer, and the second surface is at a backside of the semiconductor device layer; an insulating layer above the second surface of the semiconductor device; and a through-silicon via (TSV) traversing the insulating layer. Associated manufacturing methods of the same are also provided.

In an embodiment, a device includes: a first fin extending from a substrate; a gate stack disposed on the first fin; a source/drain region disposed in the first fin; a contact etch stop layer (CESL) disposed over the source/drain region; a gate spacer extending along a side of the gate stack; and a dielectric plug disposed between the CESL and the gate spacer, where the dielectric plug, the CESL, the gate spacer, and the source/drain region collectively define a void physically separating the gate stack from the source/drain region.

A method includes obtaining a base structure including a stack of dielectric layers disposed on a substrate. The stack of dielectric layers includes a first photosensitive dielectric layer including a first photosensitive dielectric material sensitive to a first radiation dose, a second photosensitive dielectric layer including a second photosensitive dielectric material sensitive to a second radiation dose different from the first radiation dose, and a barrier layer disposed between the first photosensitive dielectric layer and the second photosensitive dielectric layer. The method further includes forming a dual damascene structure from the base structure using a dual damascene process.

Integrated circuit devices and methods of forming the same are provided. A method according to the present disclosure includes providing a workpiece including a first metal feature in a dielectric layer and a capping layer over the first metal feature, selectively depositing a blocking layer over the capping layer, depositing an etch stop layer (ESL) over the workpiece, removing the blocking layer, and depositing a second metal feature over the workpiece such that the first metal feature is electrically coupled to the second metal feature. The blocking layer prevents the ESL from being deposited over the capping layer.

Methods for selective deposition are provided. Material is selectively deposited on a first surface of a substrate relative to a second surface of a different material composition. An inhibitor, such as a polyimide layer, is selectively formed from vapor phase reactants on the first surface relative to the second surface. A layer of interest is selectively deposited from vapor phase reactants on the second surface relative to the first surface. The first surface can be metallic while the second surface is dielectric. Accordingly, material, such as a dielectric transition metal oxides and nitrides, can be selectively deposited on metallic surfaces relative dielectric surfaces using techniques described herein.

A device includes semiconductor channel region, source/drain regions, a source/drain contact, a first dielectric layer, a second dielectric layer, and a tungsten via. The source/drain regions are at opposite sides of the semiconductor channel region. The source/drain contact is over one of the source/drain regions. The first dielectric layer is over the source/drain contact. The second dielectric layer is over the first dielectric layer. The tungsten via extends through the first and second dielectric layers to the source/drain contact. The tungsten via includes a first portion over the source/drain contact and a second portion over the first portion. The second portion includes a tungsten sidewall laterally offset from a tungsten sidewall of the first portion, and a tungsten surface interfacing a top surface of the first dielectric layer.

A wet etching chemistry to selectively remove a polymer residue on an opening embedded in a low-k dielectric layer and an underlying stop layer in a process of forming an interconnect structure is provided. The wet etching chemistry includes: two type of organic solvents, wherein a concentration of the two type of organic solvents is greater than or equal to 70%; an Alkali source amine, at least comprising a tertiary amine; an inhibitor; and water. In some embodiment, the wet etching chemistry is free of a peroxide to avoid damage to the WdC hard mask.

A method including forming an oxide layer on a first substrate and forming a second substrate on the oxide layer. Doping a first section of the second substrate while not doping a second section of the second substrate. Forming a first nano device on the second section of the second substrate and forming a second nano device on first section of the second substrate. Flipping the first substrate over to allow for backside processing of the substrate and forming at least one backside contact connected to the first nano device while backside contacts are not formed or connected to the second nano device.