Embodiments of the present disclosure generally relate to a method for etching a film stack with high selectivity and low etch recipe transition periods. In one embodiment, a method for etching a film stack having stacked pairs of oxide and nitride layers is described. The method includes transferring a substrate having a film stack formed thereon into a processing chamber, providing a first bias voltage to the substrate, etching an oxide layer of the film stack while providing the first bias voltage to the substrate, providing a second bias voltage to the substrate, the second bias voltage greater than the first bias voltage, and etching a nitride layer of the film stack while providing the second bias voltage to the substrate.

A laminate that can be used for diffusing an impurity diffusion component into a semiconductor substrate and manufactured by a method with good film formability, and which allows sufficient diffusion of the impurity diffusion component; a method for manufacturing the laminate; and a method for manufacturing a semiconductor substrate using the laminate. The laminate includes a diffusion-undergoing semiconductor substrate, an amine compound layer, and an impurity diffusion component layer, the amine compound layer is in contact with one main surface of the diffusion-undergoing semiconductor substrate, the impurity diffusion component layer is in contact with a main surface of the amine compound layer, the main surface is not in contact with the diffusion-undergoing semiconductor substrate, and the amine compound layer includes an amine compound including two or more nitrogen atoms and having an amino group constituted by at least one of the two or more nitrogen atoms; and/or an amine compound residue having one or more amino groups and bonding to the main surface via a covalent bond.

A semiconductor device with densified dielectric structures and a method of fabricating the same are disclosed. The method includes forming a fin structure, forming an isolation structure adjacent to the fin structure, forming a source/drain (S/D) region on the fin structure, depositing a flowable dielectric layer on the isolation structure, converting the flowable dielectric layer into a non-flowable dielectric layer, performing a densification process on the non-flowable dielectric layer, and repeating the depositing, converting, and performing to form a stack of densified dielectric layers surrounding the S/D region.

A semiconductor device includes a semiconductor feature, a low-k dielectric feature that is formed on the semiconductor feature, and a Si-containing layer that contains elements of silicon and that covers over the low-k dielectric feature. The Si-containing layer can prevent the low-k dielectric feature from being damaged in etch and/or annealing processes for manufacturing the semiconductor device.

Methods and apparatus for processing a substrate are provided herein. For example, a method of processing a substrate comprises a) removing oxide from a metal layer disposed in a dielectric layer on the substrate disposed in a processing chamber, b) selectively depositing a self-assembled monolayer (SAM) on the metal layer using atomic layer deposition, c) depositing a precursor while supplying water to form one of an aluminum oxide (AlO) layer on the dielectric layer or a low-k dielectric layer on the dielectric layer, d) supplying at least one of hydrogen (H.sub.2) or ammonia (NH.sub.3) to remove the self-assembled monolayer (SAM), and e) depositing one of a silicon oxycarbonitride (SiOCN) layer or a silicon nitride (SiN) layer atop the metal layer and the one of the aluminum oxide (AlO) layer on the dielectric layer or the low-k dielectric layer on the dielectric layer.

A method for forming a semiconductor device structure is provided. The semiconductor device includes forming nanowire structures stacked over a substrate and spaced apart from one another, and forming a dielectric material surrounding the nanowire structures. The dielectric material has a first nitrogen concentration. The method also includes treating the dielectric material to form a treated portion. The treated portion of the dielectric material has a second nitrogen concentration that is greater than the first nitrogen concentration. The method also includes removing the treating portion of the dielectric material, thereby remaining an untreated portion of the dielectric material as inner spacer layers; and forming the gate stack surrounding nanowire structures and between the inner spacer layers.

To manufacture an integrated circuit (IC) device, a structure in which a first material film including silicon atoms and nitrogen atoms and a second material film devoid of nitrogen atoms is formed on a substrate. A carbonyl compound having a functional group without an α-hydrogen is applied to the structure, and thus, an inhibitor is selectively formed only on an exposed surface of the first material film from among the first material film and the second material film.

A method includes coating, via chemical vapor deposition, electronics disposed on a printed circuit board (PCB) with an electrical insulation coating of between one micron to 25 microns. The method further include depositing, on the electrical insulation coating, a metallic nano-layer comprising a porous metallic nano-structure. The method further includes, after the coating and the depositing, immersing the PCB in a water-based fluid to cool the electronics while the electronics are powered on.

An etching method includes: (a) providing a substrate including a first region containing silicon and nitrogen and a second region containing silicon and oxygen; (b) forming a tungsten-containing deposit on the first region using a first plasma generated from a first processing gas containing fluorine, tungsten, and at least one selected from a group consisting of carbon and hydrogen; and (c) after (b), etching the second region using a second plasma generated from a second processing gas different from the first processing gas.

A method for fabricating a semiconductor device includes forming a line structure including a first contact plug on a semiconductor substrate and a conductive line on the first contact plug, forming a low-k layer having a first low-k, which covers a top surface and side walls of the line structure, performing a converting process on the low-k layer to form a non-converting portion adjacent to side walls of the first contact plug and maintains the first low-k and a converting portion adjacent to side walls of the conductive line and having a second low-k that is lower than the first low-k, and forming a second contact plug which is adjacent to the first contact plug with the non-converting portion therebetween while being adjacent to the conductive line with the converting portion therebetween.