An IC structure includes a first transistor, a second transistor, a dielectric fin, a dielectric cap, a backside metal structure, and a source/drain contact. The first transistor includes a first channel region, a first gate structure, and first source/drain features disposed on opposite sides of the first gate structure. The second transistor includes a second channel region, a second gate structure, and second source/drain features disposed on opposite sides of the second gate structure. The dielectric fin is disposed between the first and second transistors. The dielectric cap interfaces a backside surface of the dielectric fin. The source/drain contact abuts the dielectric fin and is electrically coupled to a first one of the first source/drain features by way of a silicide layer and electrically coupled to the backside metal rail by way of physical contact established by the source/drain contact and the backside metal rail.

Embodiments of the present invention provide a method for removing a barrier layer of a metal interconnection on a wafer, which remove a single-layer metal ruthenium barrier layer. A method comprises: oxidizing step, is to oxidize the single-layer metal ruthenium barrier layer into a ruthenium oxide layer by electrochemical anodic oxidation process; oxide layer etching step, is to etch the ruthenium oxide layer with etching liquid to remove the ruthenium oxide layer. The present invention also provides a method for removing a barrier layer of a metal interconnection on a wafer, using in a structure of a process node of 10 nm and below, wherein the structure comprises a substrate, a dielectric layer, a barrier layer and a metal layer, the dielectric layer is deposited on the substrate and recessed areas are formed on the dielectric layer, the barrier layer is deposited on the dielectric layer, the metal layer is deposited on the barrier layer, wherein the metal layer is a copper layer, the barrier layer is a single-layer metal ruthenium layer, and the method comprises: thinning step, is to thin the metal layer; removing step, is to remove the metal layer; oxidizing step, is to oxidize the barrier layer, and the oxidizing step uses an electrochemical anodic oxidation process; oxide layer etching step, is to etch the oxidized barrier layer.

There is provided a semiconductor device capable of capable of improving element performance and reliability. A semiconductor device includes a lower conductive pattern disposed on a substrate, an upper conductive pattern disposed on the lower conductive pattern, and a first plug pattern disposed between the lower conductive pattern and the upper conductive pattern and connected to the lower conductive pattern and the upper conductive pattern. The first plug pattern includes a first barrier pattern that defines a first plug recess and a first plug metal pattern that fills the first plug recess, and the first plug metal pattern includes a first molybdenum pattern and a first tungsten pattern disposed on the first molybdenum pattern.

Generally, the present disclosure provides example embodiments relating to conductive features, such as metal contacts, vias, lines, etc., and methods for forming those conductive features. In a method embodiment, a dielectric layer is formed on a semiconductor substrate. The semiconductor substrate has a source/drain region. An opening is formed through the dielectric layer to the source/drain region. A silicide region is formed on the source/drain region and a barrier layer is formed in the opening along sidewalls of the dielectric layer by a same Plasma-Enhance Chemical Vapor Deposition (PECVD) process.

Devices and methods that include for configuring a profile of a liner layer before filling an opening disposed over a semiconductor substrate. The liner layer has a first thickness at the bottom of the opening and a second thickness a top of the opening, the second thickness being smaller that the first thickness. In an embodiment, the filled opening provides a contact structure.

Microelectronic deviceshaving at least one conductive contact structure adjacent a silicide regionare formed using methods that avoid unintentional contact expansion and contact reduction. A first metal nitride liner is formed in a contact opening, and an exposed surface of a polysilicon structure is thereafter treated (e.g., cleaned and dried) in preparation for formation of a silicide region. During the pretreatments (e.g., cleaning and drying), neighboring dielectric material is protected by the presence of the metal nitride liner, inhibiting expansion of the contact opening. After forming the silicide region, a second metal nitride liner is formed on the silicide region before a conductive material is formed to fill the contact opening and form a conductive contact structure (e.g., a memory cell contact structure, a peripheral contact structure).

A semiconductor structure includes a fin structure formed over a substrate. The structure also includes a gate structure formed across the fin structure. The structure also includes source/drain epitaxial structures formed on opposite sides of the gate structure. The structure also includes an inter-layer dielectric (ILD) structure formed over the gate structure. The structure also includes a contact blocking structure formed through the ILD structure over the source/drain epitaxial structure. A lower portion of the contact blocking structure is surrounded by an air gap, and the air gap is covered by a portion of the ILD structure.

A device includes a gate structure, a source/drain structure, a source/drain conductor, a barrier layer, and a dielectric liner layer. The gate structure is over a semiconductor structure and includes a gate dielectric layer and at least one titanium-containing metal layer over the gate dielectric layer. The source/drain structure is adjacent the gate structure and a sidewall of the semiconductor structure. The source/drain conductor is over the source/drain structure. The barrier layer warps around the source/drain conductor. The dielectric liner layer is on a sidewall of the barrier layer. Both the dielectric liner layer and the barrier layer extend into the source/drain structure.