A semiconductor device according to the present disclosure includes a first plurality of gate-all-around (GAA) devices in a first device area and a second plurality of GAA devices in a second device area. Each of the first plurality of GAA devices includes a first vertical stack of channel members extending along a first direction, and a first gate structure over and around the first vertical stack of channel members. Each of the second plurality of GAA devices includes a second vertical stack of channel members extending along a second direction, and a second gate structure over and around the second vertical stack of channel members. Each of the first plurality of GAA devices includes a first channel length and each of the second plurality of GAA devices includes a second channel length smaller than the first channel length.

Embodiments described herein relate to plasma processes. A plasma process includes generating a plasma containing negatively charged oxygen ions. A substrate is exposed to the plasma. The substrate is disposed on a pedestal while being exposed to the plasma. While exposing the substrate to the plasma, a negative direct current (DC) bias voltage is applied to the pedestal to repel the negatively charged oxygen ions from the substrate.

There is provision of a processing method including a) depositing deposits on a patterned mask layer formed over an etching film; b) removing a part of the mask layer, a part of the deposits, or both the part of the mask layer and the part of the deposits; and c) repeating a) and b) at least once, thereby causing a taper angle of a side surface of a pattern formed in the mask layer to be a desired angle.

A semiconductor device according to the present disclosure includes a first plurality of gate-all-around (GAA) devices in a first device area and a second plurality of GAA devices in a second device area. Each of the first plurality of GAA devices includes a first vertical stack of channel members extending along a first direction, and a first gate structure over and around the first vertical stack of channel members. Each of the second plurality of GAA devices includes a second vertical stack of channel members extending along a second direction, and a second gate structure over and around the second vertical stack of channel members. Each of the first plurality of GAA devices includes a first channel length and each of the second plurality of GAA devices includes a second channel length smaller than the first channel length.

A method for separating semiconductor dies of a semiconductor die assembly comprises depositing a first coating on a first surface of the assembly. The assembly comprises a die wafer having a plurality of semiconductor dies and first and second surfaces. A first portion of the die wafer and the first coating is removed between adjacent semiconductor dies to form trenches having an intermediate depth in the die wafer between first and second surfaces such that die corners are formed on either side of the trenches. A protective coating is deposited on the first surface of the die assembly to cover the die corners, trenches and at least a portion of the first coating. The first coating is selectively removed such that portions of the protective coating covering die corners and trenches remain on the die wafer. Adjacent semiconductor dies are separated and the protective coating remains covering the die corners.

Disclosed herein is a high throughput method for providing directional protection to a three dimensional feature on a substrate by forming a multi-layer amorphous carbon-containing coating with tunable conformality thereon. Forming the multi-layer amorphous carbon-containing coating with tunable conformality includes depositing a base layer onto a horizontal surface of the three dimensional features, and a second layer over the base layer and onto a first portion of a vertical or inclined surface of the three dimensional feature. The base layer includes a first material with a first sticking coefficient and the second layer includes a second material with a second sticking coefficient that is smaller than the first sticking coefficient. The first material includes no fluorine or less fluorine than the second material. Also disclosed herein is a method of manufacturing a three dimensional device as well as three dimensional devices.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a substrate, conductive layers positioned on the substrate, a carbon hard mask layer positioned on the conductive layers, an insulating layer including a lower portion and an upper portion, and a conductive via positioned along the upper portion of the insulating layer and the carbon hard mask layer and positioned on one of the adjacent pair of the conductive layers. The lower portion is positioned along the carbon hard mask layer and positioned between an adjacent pair of the conductive layers, and the upper portion is positioned on the lower portion and on the carbon hard mask layer.

A substrate processing apparatus includes: a chamber having at least one gas inlet and at least one gas outlet; a substrate support disposed in the chamber; and a controller. The controller causes (a) placing a substrate on the substrate support, the substrate including a base layer and a first layer formed on the base layer; (b) etching the first layer to form a recess in the first layer; (c) when determined that the recess satisfies a predetermined condition, forming a first film on a bottom surface of the recess by forming an inhibitor on the bottom surface of the recess, a predetermined gas species being not adsorbed to the first film; (c) after (b), forming a second film on a side wall of the recess using the predetermined gas species as a precursor gas; and (d) etching the first layer through the recess.

A plasma processing method executed by a plasma processing apparatus includes a first step, a second step, and an etching step. In the first step, the plasma processing apparatus forms a first film on a processing target in which a plurality of openings having a predetermined pattern are formed. In the second step, the plasma processing apparatus forms a second film having an etching rate lower than that of the first film on the processing target on which the first film is formed, and having different film thicknesses on the side surfaces of the openings according to the sizes of the openings. In the etching step, the plasma processing apparatus performs etching from above the second film under a predetermined processing condition until a portion of the first film is removed from at least a portion of the processing target.

A substrate processing method includes step (a) of adsorbing a precursor on a side wall surface of a substrate where the side wall surface defines a recess in the substrate. The substrate processing method further includes step (b) of supplying a first chemical species and a second chemical species to the substrate. The first chemical species forms a film from the precursor on the side wall surface, and the second chemical species suppresses an increase of the thickness of the film. Steps (a) and (b) are alternately repeated.