Methods of patterning semiconductor devices and semiconductor devices formed by the same are disclosed. In an embodiment, a method includes forming a first dielectric layer over a semiconductor substrate; forming a first hard mask layer over the first dielectric layer; etching the first hard mask layer to form a first opening exposing a top surface of the first dielectric layer; performing a plasma treatment process on the top surface of the first dielectric layer and a top surface of the first hard mask layer; after performing the plasma treatment process, selectively depositing a spacer on a side surface of the first hard mask layer, the top surface of the first dielectric layer and the top surface of the first hard mask layer being free from the spacer after selectively depositing the spacer; and etching the first dielectric layer using the spacer as a mask.

A method of fabricating air gaps in advanced semiconductor devices for low capacitance interconnects. The method includes exposing a substrate to a gas pulse sequence to deposit a material that forms an air gap between raised features.

A multilayer composite structure and a method of preparing a multilayer composite structure are provided. The multilayer composite structure comprises a semiconductor handle substrate having a minimum bulk region resistivity of at least about 500 ohm-cm and an isolation region that impedes the transfer of charge carriers along the surface of the handle substrate and reduces parasitic coupling between RF devices.

A substrate processing system for depositing film on a substrate includes a processing chamber defining a reaction volume and including a substrate support for supporting the substrate. A gas delivery system is configured to introduce process gas into the reaction volume of the processing chamber. A plasma generator is configured to selectively generate RF plasma in the reaction volume. A clamping system is configured to clamp the substrate to the substrate support during deposition of the film. A backside purging system is configured to supply a reactant gas to a backside edge of the substrate to purge the backside edge during the deposition of the film.

Embodiments described herein generally relate to enable the formation of a metal gate structure with a reduced effective oxide thickness over a similar structure formed via conventional methods. A plasma hydrogenation process followed by a plasma nitridization process is performed on a metal nitride layer in a film stack, thereby removing oxygen atoms disposed within layers of the film stack and, in some embodiments eliminating an oxygen-containing interfacial layer disposed within the film stack. As a result, an effective oxide thickness of the metal gate structure is reduced with little or no accompanying flatband voltage shift. Further, the metal gate structure operates with an increased leakage current that is as little as one quarter the increase in leakage current associated with a similar metal gate structure formed via conventional techniques.

A method of forming a material layer includes providing a substrate into a reaction chamber, providing a source material onto a substrate, the source material being a precursor of a metal or semimetal having a ligand, providing an ether-based modifier on the substrate, purging an inside of the reaction chamber, and reacting a reaction material with the source material to form the material layer.

Processes are provided herein for deposition of organic films. Organic films can be deposited, including selective deposition on one surface of a substrate relative to a second surface of the substrate. For example, polymer films may be selectively deposited on a first metallic surface relative to a second dielectric surface. Selectivity, as measured by relative thicknesses on the different layers, of above about 50% or even about 90% is achieved. The selectively deposited organic film may be subjected to an etch process to render the process completely selective. Processes are also provided for particular organic film materials, independent of selectivity. Masking applications employing selective organic films are provided. Post-deposition modification of the organic films, such as metallic infiltration and/or carbon removal, is also disclosed.

The invention provides a process for forming crack-free dielectric films on a substrate. The process comprises the application of a dielectric precursor layer of a thickness from about 0.3 μm to about 1.0 μm to a substrate. The deposition is followed by low temperature heat pretreatment, prepyrolysis, pyrolysis and crystallization step for each layer. The deposition, heat pretreatment, prepyrolysis, pyrolysis and crystallization are repeated until the dielectric film forms an overall thickness of from about 1.5 μm to about 20.0 μm and providing a final crystallization treatment to form a thick dielectric film. The process provides a thick crack-free dielectric film on a substrate, the dielectric forming a dense thick crack-free dielectric having an overall dielectric thickness of from about 1.5 μm to about 20.0 μm.

A method of manufacturing a semiconductor device for forming a thin film having low permittivity, high etching resistance and high leak resistance is provided. The method includes: forming a film containing a predetermined element, oxygen, carbon and nitrogen on a substrate by performing a cycle a predetermined number of times. The cycle includes: (a) supplying a source gas containing the predetermined element and a halogen element to the substrate; (b) supplying a first reactive gas containing the three elements including carbon, nitrogen and hydrogen wherein a number of carbon atoms in each molecule of the first reactive gas is greater than that of nitrogen atoms in each molecule of the first reactive gas to the substrate; (c) supplying a nitriding gas as a second reactive gas to the substrate; and (d) supplying an oxidizing gas as a third reactive gas to the substrate, wherein (a) through (d) are non-simultaneously performed.

Method of manufacturing a semiconductor device is described that uses sidewall protection of a recessed feature to prevent loss of critical dimension during a cleaning process to remove etch residue. According to one embodiment, the method includes providing a substrate containing a film thereon having a recessed feature with a sidewall and a bottom portion, depositing a conformal film on the sidewall and on the bottom portion, removing the conformal film from the bottom portion in an anisotropic etching process, where the remaining conformal film forms a protection film on the sidewall, and performing a cleaning process that removes etch residue from the recessed feature without etching the protection film or the sidewall.