A method may include depositing a carbon layer on a substrate using physical vapor deposition, wherein the carbon layer exhibits compressive stress, and is characterized by a first stress value; and directing a dose of low-mass species into the carbon layer, wherein, after the directing, the carbon layer exhibits a second stress value, less compressive than the first stress value.

A protective film forming method is provided. In the method, substantially an entire surface of a silicon-containing underfilm is terminated with fluorine by supplying a fluorine-containing gas to the silicon-containing underfilm formed on a substrate having a surface including a plurality of recesses and a flat surface provided between the adjacent recesses. A surface of the silicon-containing underfilm formed on the flat surface of the substrate is nitrided by supplying a nitriding gas converted to plasma to the silicon-containing underfilm terminated with fluorine such that a silicon adsorption site is formed on the surface of the silicon-containing underfilm formed on the flat surface of the substrate. A silicon-containing gas is adsorbed on the silicon adsorption site by supplying the silicon-containing gas to the silicon-containing underfilm.

A fabricating method of a stop layer includes providing a substrate. The substrate is divided into a memory region and a peripheral circuit region. Two conductive lines are disposed within the peripheral circuit region. Then, an atomic layer deposition is performed to form a silicon nitride layer to cover the conductive lines. Later, after forming the silicon nitride layer, a silicon carbon nitride layer is formed to cover the silicon nitride layer. The silicon carbon nitride layer serves as a stop layer.

There is provided a method of forming a predetermined film by alternately supplying a film-forming raw material gas and a reaction gas onto a workpiece by an atomic layer deposition (ALD), the method including: beginning an ALD-based film formation at a first temperature at which an adsorption of the film-forming raw material gas occurs; continuing the ALD-based film formation while increasing the first temperature; and completing the ALD-based film formation at a second temperature at which a decomposition of the film-forming raw material gas occurs.

In an embodiment, in the method for processing a workpiece including an etching target layer containing silicon oxide, a mask provided on the etching target layer, and an opening provided in the mask and exposing the etching target layer, according to the embodiment, the etching target layer is etched by removing the etching target layer for each atomic layer through repetitive execution of a sequence of generating plasma of a first processing gas containing nitrogen, forming a mixed layer containing ions included in the plasma on an atomic layer on an exposed surface of the etching target layer, generating plasma of a second processing gas containing fluorine, and removing the mixed layer by radicals included in the plasma. The plasma of the second processing gas contains the radicals that remove the mixed layer containing silicon nitride.

A pattern is defined in a dielectric layer. The dielectric layer includes a low-k dielectric region and a high-k dielectric region. The high-k dielectric region includes a phase change material which is an alloy of tantalum and nitrogen and is a high-k insulator in a deposited state. The pattern includes a first set of features in the low-k dielectric region and a second set of features in the high-k dielectric region. A surface treatment process is performed on the phase change layer to produce a top surface layer having electrically conductive properties. A metal layer is deposited in the first and second set of features. Thus, a set of conductive lines is formed in the low-k dielectric region and a metal insulator metal capacitor in the high-k dielectric region.

The present disclosure relates to a semiconductor device and a manufacturing method, and more particularly to a semiconductor device having an enhanced gap fill layer in trenches. The present disclosure provides a novel gap fill layer formed using a multi-step deposition and in-situ treatment process. The deposition process can be a flowable chemical vapor deposition (FCVD) utilizing one or more assist gases and molecules of low reactive sticking coefficient (RSC). The treatment process can be an in-situ process after the deposition process and includes exposing the deposited gap fill layer to plasma activated assist gas. The assist gas can be formed of ammonia. The low RSC molecule can be formed of trisilylamin (TSA) or perhydropolysilazane (PHPS).

A flowable chemical vapor deposition method including depositing a dielectric film precursor on a substrate in a flowable form; depositing an oligomerization agent on the substrate; forming a dielectric film from the dielectric film precursor; and curing the dielectric film under a pressure greater than atmospheric pressure. A method including depositing a dielectric film precursor as a liquid on a substrate in the presence of an oligomerization agent; treating the deposited dielectric film precursor to inhibit outgassing; and curing the dielectric film precursor to form a dielectric film. A method including delivering a dielectric film precursor as a vapor to a substrate including gap structures between device features; condensing the dielectric film precursor on the substrate to a liquid; flowing the liquid into the gap structures; and curing the dielectric film precursor under a pressure of 15 pounds per square inch gauge or greater.

A nitrogen plasma treatment is used on an adhesion layer of a contact plug. As a result of the nitrogen plasma treatment, nitrogen is incorporated into the adhesion layer. When a contact plug is deposited in the opening, an interlayer of a metal nitride is formed between the contact plug and the adhesion layer. A nitrogen plasma treatment is used on an opening in an insulating layer. As a result of the nitrogen plasma treatment, nitrogen is incorporated into the insulating layer at the opening. When a contact plug is deposited in the opening, an interlayer of a metal nitride is formed between the contact plug and the insulating layer.

According to one embodiment, a semiconductor device includes a first semiconductor layer including a nitride semiconductor, a first electrode separated from the first semiconductor layer in a first direction, and a first insulating film including silicon and oxygen and being provided between the first semiconductor layer and the first electrode. The first insulating film has a first thickness in the first direction. The first insulating film includes a first position, and a distance between the first position and the first semiconductor layer is of the first thickness. A first hydrogen concentration of hydrogen at the first position is 2.510.sup.19 atoms/cm.sup.3 or less.