A method includes providing a dielectric layer; forming a metal line in the dielectric layer; forming an etch stop layer on the metal line, wherein the etch stop layer includes a metal atom bonded with a hydroxyl group; performing a treatment process to the etch stop layer to displace hydrogen in the hydroxyl group with an element other than hydrogen; partially etching the etch stop layer to expose the metal line; and forming a conductive feature above the etch stop layer and in physical contact with the metal line.

A method of forming an oxide film including two non-oxygen elements includes providing a first source material on a substrate, the first source material including a first central element, providing an electron donor compound to be bonded to the first source material, providing a second source material on the substrate after the providing of the electron donor compound, the second source material including a second central element, and providing an oxidant on the substrate.

A film-forming method in which film-formation is performed by heat-treating a mist of a raw material solution, the method including: dissolving metal gallium in an acidic solution containing at least one of hydrobromic acid and hydroiodic acid to prepare the raw material solution having a concentration of a metal impurity of less than 2%; and atomizing the raw material solution into a mist, and performing film-forming. This method can provide a film-forming method that can form a film having good crystallinity at a high film-forming rate.

An example embodiment of the present disclosure involves a method for semiconductor device fabrication. The method comprises providing a structure that includes a conductive component and an interlayer dielectric (ILD) that includes silicon and surrounds the conductive component, and forming, over the conductive component and the ILD, an etch stop layer (ESL) that includes metal oxide. The ESL includes a first portion in contact with the conductive component and a second portion in contact with the ILD. The method further comprises baking the ESL to transform the metal oxide located in the second portion of the ESL into metal silicon oxide, and selectively etching the ESL so as to remove the first portion of the ESL but not the second portion of the ESL.

Embodiments of the present disclosure are related to methods of preventing aluminum diffusion in a metal gate stack (e.g., high-κ metal gate (HKMG) stacks and nMOS FET metal gate stacks). Some embodiments relate to a barrier layer for preventing aluminum diffusion into high-κ metal oxide layers. The barrier layer described herein is configured to reduce threshold voltage (V.sub.t) shift and reduce leakage in the metal gate stacks. Additional embodiments relate to methods of forming a metal gate stack having the barrier layer described herein. The barrier layer may include one or more of amorphous silicon (a-Si), titanium silicon nitride (TiSiN), tantalum nitride (TaN), or titanium tantalum nitride (TiTaN).

A method comprises providing a semiconductor alloy layer on a semiconductor substrate, forming a gate structure on the semiconductor alloy layer, forming source and drain regions in the semiconductor substrate on both sides of the gate structure, removing at least a portion of the semiconductor alloy layer overlying the source and drain regions, and forming a metal silicide region over the source and drain regions.

A semiconductor device includes a substrate, a first conductive feature disposed in a top portion of the substrate, a metal containing layer disposed on the first conductive feature, and a second conductive feature disposed on and through the metal containing layer and in physical contact with the first conductive feature. The metal containing layer includes an M-O—X group, M representing a metal atom, O representing an oxygen atom, and X representing an element other than hydrogen.

Methods of forming patterned structures suitable for a multiple patterning process are disclosed. Exemplary methods include forming a layer overlying the substrate by providing a precursor to the reaction chamber for a precursor pulse period, providing a reactant to the reaction chamber for a reactant pulse period, applying a first plasma power having a first frequency (e.g., less than 1 MHz) for a first plasma power period, and optionally applying a second plasma power having a second frequency for a second plasma power period, wherein the first frequency is different than the second frequency.

Methods of forming metal silicon oxide layers and metal silicon oxynitride layers are disclosed. Exemplary methods include providing a silicon precursor to the reaction chamber for a silicon precursor pulse period, providing a first metal precursor to the reaction chamber for a first metal precursor pulse period, and providing a first reactant to the reaction chamber for a first reactant pulse period, wherein the silicon precursor pulse period and the first metal precursor pulse period overlap.

A device includes a semiconductive substrate, a fin structure, and an isolation material. The fin structure extends from the semiconductive substrate. The isolation material is over the semiconductive substrate and adjacent to the fin structure, wherein the isolation material includes a first metal element, a second metal element, and oxide.