Embodiments of methods for treating dielectric layers are provided herein. In some embodiments, a method of treating a dielectric layer disposed on a substrate supported in a process chamber includes: (a) exposing the dielectric layer to an active radical species formed in a plasma for a first period of time; (b) heating the dielectric layer to a peak temperature of about 900 degrees Celsius to about 1200 degrees Celsius; and (c) maintaining the peak temperature for a second period of time of about 1 second to about 20 seconds.

Provided are methods of depositing a film in high aspect ratio (AR) structures with small dimensions. The method provides flowable deposition for seamless gap-fill, film densification by low temperature inductively coupled plasma (ICP) treatment (<600° C.), optional film curing, and etch back to form a low-k dielectric film having a dielectric constant, k-value less than 3.

Improved methods are provided for transferring a photoresist pattern onto one or more underlying layers. In the disclosed embodiments, etch selectivity between a photoresist layer and one or more underlying layers is improved by pre-treating the underlying layer(s) with a plasma before the photoresist layer is deposited and patterned to form a photoresist pattern. The plasma modifies the underlying layer(s) by implanting ions into the underlying layer(s) to form a modified layer. When the modified layer is subsequently etched to transfer the photoresist pattern onto the modified layer, the presence of ions within the modified layer increases the etch rate of the modified layer, compared to the etch rate that the underlying layer(s) would have exhibited without plasma pre-treatment. The increased etch rate of the modified layer improves etch selectivity between the photoresist layer and the modified layer and mitigates defects during the photoresist pattern transfer process.

A semiconductor device includes a first insulator, a transistor over the first insulator, a second insulator over the transistor, and a third insulator over the second insulator. The transistor includes an oxide semiconductor. The amount of oxygen released from the second insulator when converted into oxygen molecules is larger than or equal to 1×10.sup.14 molecules/cm.sup.2 and smaller than 1×10.sup.16 molecules/cm.sup.2 in thermal desorption spectroscopy at a surface temperature of a film of the second insulator of higher than or equal to 50° C. and lower than or equal to 500° C. The second insulator includes oxygen, nitrogen, and silicon.

Techniques herein provide methods for depositing spin-on metal materials for creating metal hard mask (MHM) structures without voids in the deposition. This includes effective spin-on deposition of TiOx, ZrOx, SnOx, HFOx, TaOx, et cetera. Such materials can help to provide differentiation of material etch resistivity for differentiation. By enabling spin-on metal hard mask (MHM) for use with a multi-line layer, a slit-based or self-aligned blocking strategy can be effectively used. Techniques herein include identifying a fill material to fill particular openings in a given relief pattern, modifying a surface energy value of surfaces within the opening such that a contact angle value of an interface between the fill material in liquid form and the sidewall or floor surfaces enables gap-free or void-free filling.

A method for forming a group III-V semiconductor channel region in a transistor is provided herein. The method includes exposing a substrate including an oxide layer to a first plasma to treat the oxide layer, exposing the treated oxide layer to a second plasma to convert the oxide layer to an evaporable layer, evaporating the evaporable layer to expose a group III-V semiconductor material surface, and exposing the group III-V semiconductor material surface to an oxygen containing gas to oxidize the group III-V semiconductor material. The processes may be repeated until a recessed depth having a predetermined depth is formed. A group III-V semiconductor channel is then formed in the predetermined recessed depth. The control of the height of the group III-V semiconductor channel is improved.

Methods for pre-cleaning substrates having metal and dielectric surfaces are described. The substrate is exposed to a strong reductant to remove contaminants from the metal surface and damage the dielectric surface. The substrate is then exposed to an oxidation process to repair the damage to the dielectric surface and oxidize the metal surface. The substrate is then exposed to a weak reductant to reduce the metal oxide to a pure metal surface without substantially affecting the dielectric surface. Processing tools and computer readable media for practicing the method are also described.

Semiconductor devices and methods of fabricating semiconductor devices are provided. The present disclosure provides a semiconductor device that includes a first fin structure and a second fin structure each extending from a substrate; a first gate segment over the first fin structure and a second gate segment over the second fin structure; a first isolation feature separating the first and second gate segments; a first source/drain (S/D) feature over the first fin structure and adjacent to the first gate segment; a second S/D feature over the second fin structure and adjacent to the second gate segment; and a second isolation feature also disposed in the trench. The first and second S/D features are separated by the second isolation feature, and a composition of the second isolation feature is different from a composition of the first isolation feature.

A technique of manufacturing a semiconductor device of stable operation is provided. There is provided a method of manufacturing a semiconductor device comprising a first process of forming an insulating film from a nitrogen-containing organic metal used as raw material, on a semiconductor layer by atomic layer deposition; a second process of processing the insulating film by oxygen plasma treatment in an atmosphere including at least one of oxygen and ozone; and a third process of processing the insulating film by heat treatment in a nitrogen-containing atmosphere, after the second process.

A method for fabricating a semiconductor device includes: forming a silicon nitride film having a refractive index equal to or larger than 2.2 on a nitride semiconductor layer; and introducing at least one of elements that are oxygen, nitrogen, fluorine, phosphorus, sulfur and selenium into the silicon nitride film, the silicon nitride film including the at least one of elements remaining on the nitride semiconductor layer. The at least one of elements is introduced by a process of exposing the silicon nitride film to plasma including the at least one of elements, a process of ion-implanting the at least one of elements into the silicon nitride film, or a process of thermally diffusing the at least one of elements into the silicon nitride film. The silicon nitride film is formed in contact with a surface of the nitride semiconductor layer.