In one embodiment, a semiconductor device includes a stacked film alternately including a plurality of electrode layers and a plurality of insulating layers. The device further includes a first insulator, a charge storage layer, a second insulator and a first semiconductor layer that are disposed in order in the stacked film. The device further includes a plurality of first films disposed between the first insulator and the plurality of insulating layers. Furthermore, at least one of the first films includes a second semiconductor layer.

This disclosure relates to a composition that includes at least one first ruthenium removal rate enhancer; at least one copper removal rate inhibitor; at least one low-k removal rate inhibitor; and an aqueous solvent.

A method of manufacturing a semiconductor device includes forming an underlying structure in a first area and a second area over a substrate. A first layer is formed over the underlying structure. The first layer is removed from the second area while protecting the first layer in the first area. A second layer is formed over the first area and the second area, wherein the second layer has a smaller light transparency than the first layer. The second layer is removed from the first area, and first resist pattern is formed over the first layer in the first area and a second resist pattern over the second layer in the second area.

A variety of applications can include apparatus having a memory device with an array of vertical strings of memory cells for the memory device with data lines coupled to the vertical strings, where the data lines have been formed by a metal liner deposition process. In the metal liner deposition, a metal can be formed on a patterned dielectric region. The metal liner deposition process allows for construction of the height of the data lines to be well controlled with selection of a thickness for the dielectric region used in forming the metal liner. Use of a metal liner deposition provides a controlled mechanism to reduce data line capacitance by being able to select liner thickness in forming the data lines. The use of the dielectric region with the metal liner deposition can allow the fabrication of the data lines to avoid pitch double or pitch quad processes.

A method of fabricating semiconductor fins, including, patterning a film stack to produce one or more sacrificial mandrels having sidewalls, exposing the sidewall on one side of the one or more sacrificial mandrels to an ion beam to make the exposed sidewall more susceptible to oxidation, oxidizing the opposite sidewalls of the one or more sacrificial mandrels to form a plurality of oxide pillars, removing the one or more sacrificial mandrels, forming spacers on opposite sides of each of the plurality of oxide pillars to produce a spacer pattern, removing the plurality of oxide pillars, and transferring the spacer pattern to the substrate to produce a plurality of fins.

Embodiments of the disclosure provide an improved apparatus and methods for nitridation of stacks of materials. In one embodiment, a method for processing a substrate in a processing region of a process chamber is provided. The method includes generating and flowing plasma species from a remote plasma source to a delivery member having a longitudinal passageway, flowing plasma species from the longitudinal passageway to an inlet port formed in a sidewall of the process chamber, wherein the plasma species are flowed at an angle into the inlet port to promote collision of ions or reaction of ions with electrons or charged particles in the plasma species such that ions are substantially eliminated from the plasma species before entering the processing region of the process chamber, and selectively incorporating atomic radicals from the plasma species in silicon or polysilicon regions of the substrate.

An etching method is provided. In the etching method, a protective film-forming gas including an amine gas is supplied to a substrate having a surface on which a first film and a second film are formed, the first film and the second film having respective properties of being etched by an etching gas, and a protective film is formed to cover the first film such that the first film is selectively protected between the first film and the second film when the etching gas is supplied. Further, the second film is selectively etched by supplying the etching gas to the substrate after the protective film is formed.

A manufacturing system performs a deposition of an etch-compatible film over a substrate. The etch-compatible film includes a first surface and a second surface opposite to the first surface. The manufacturing system performs a partial removal of the etch-compatible film to create a surface profile on the first surface with a plurality of depths relative to the substrate. The manufacturing system performs a deposition of a second material over the profile created in the etch-compatible film. The manufacturing system performs a planarization of the second material to obtain a plurality of etch heights of the second material in accordance with the plurality of depths in the profile created in the etch-compatible film. The manufacturing system performs a lithographic patterning of a photoresist deposited over the planarized second material to obtain the plurality of etch heights and one or more duty cycles in the second material.

A film forming method includes: providing the substrate into the processing container; forming a metal-based film on the substrate within the processing container; and subsequently, supplying a Si-containing gas into the processing container in a state in which the substrate is provided within the processing container.

A film forming method includes: providing the substrate into the processing container; forming a metal-based film on the substrate within the processing container; and subsequently, supplying a Si-containing gas into the processing container in a state in which the substrate is provided within the processing container.