Abstract: Substrate processing techniques are described in which an etch protection layer that is formed as part of an etch process forms in a self-limiting nature. Thus, over deposition effects are minimized, particularly in the corners of etched polygonal holes. In one embodiment, the layer being etched contains silicon and the protective layer comprises a silicon oxide (SixOy). The process may include the use of a cyclical series of etch and protective layer formation steps. In the case of a silicon oxide based protective layer, a thin protective layer of silicon oxide may be formed in a limiting and controllable manner due to the nature of the oxygen atom interaction with silicon and newly formed silicon oxide protective layers. In this manner, a polygonal hole may be formed without detrimental over deposition of a protective layer in corners of the hole.

Abstract: A method of high-throughput dry etching of silicon oxide and silicon nitride materials by in-situ autocatalyst formation. The method includes providing a substrate having a film thereon in a process chamber, the film containing silicon oxide, silicon nitride, or both silicon oxide and silicon nitride, introducing an etching gas containing fluorine and hydrogen, and setting a gas pressure in the process chamber that is between about 1 mTorr and about 300 mTorr, and a substrate temperature that is below about ?30° C. The method further includes plasma-exciting the etching gas, and exposing the film to the plasma-excited etching gas, where the film is continuously etched during the exposing.

Abstract: A method of forming a semiconductor device includes depositing a first layer over a substrate and patterning the first layer using an extreme ultraviolet (EUV) lithography process to form a patterned layer and expose portions of the substrate. The method includes, in a plasma processing chamber, generating a first plasma from a gas mixture including SiCl4 and one or more of argon, helium, nitrogen, and hydrogen. The method includes exposing the substrate to the first plasma to deposit a second layer including silicon over the patterned layer.

Abstract: A method for selective plasma etching of silicon oxide relative to silicon nitride is described. The method includes providing a substrate containing a silicon oxide film and a silicon nitride film, and selectively etching the silicon oxide film relative to the silicon nitride film by: a1) exposing the substrate to a plasma-excited passivation gas containing carbon, sulfur, or both carbon and sulfur, where the plasma-excited passivation gas does not contain fluorine or hydrogen, and b1) exposing the substrate to a plasma-excited etching gas containing a fluorine-containing gas. The method can further include, between a1) and b1), an additional step of a2) exposing the substrate to a plasma-excited additional passivation gas containing a fluorocarbon gas, hydrofluorocarbon gas, a hydrochlorocarbon gas, a hydrochlorofluorocarbon gas, or a hydrocarbon gas, or a combination thereof.

Abstract: A method for selective etching of silicon oxide relative to silicon nitride includes exposing a substrate to a first gas that forms a first layer on the silicon oxide film and a second layer on the silicon nitride film, where the first gas contains boron, aluminum, or both boron and aluminum, exposing the substrate to a nitrogen-containing gas that reacts with the first layer to form a first nitride layer on the silicon oxide film and reacts with the second layer to form a second nitride layer on the silicon nitride film, where a thickness of the second nitride layer is greater than a thickness of the first nitride layer. The method further includes exposing the substrate to an etching gas that etches the first nitride layer and silicon oxide film, where the second nitride layer protects the silicon nitride film from etching by the etching gas.

Abstract: A method for selective plasma etching of silicon oxide relative to silicon nitride is described. The method includes providing a substrate containing a silicon oxide film and a silicon nitride film, and selectively etching the silicon oxide film relative to the silicon nitride film by: a1) exposing the substrate to a plasma-excited passivation gas containing carbon, sulfur, or both carbon and sulfur, where the plasma-excited passivation gas does not contain fluorine or hydrogen, and b1) exposing the substrate to a plasma-excited etching gas containing a fluorine-containing gas. The method can further include, between a1) and b1), an additional step of a2) exposing the substrate to a plasma-excited additional passivation gas containing a fluorocarbon gas, hydrofluorocarbon gas, a hydrochlorocarbon gas, a hydrochlorofluorocarbon gas, or a hydrocarbon gas, or a combination thereof.

Abstract: Methods for the atomic layer etch (ALE) of tungsten or other metal layers are disclosed that use in part sequential oxidation and reduction of tungsten/metal layers to achieve target etch parameters. For one embodiment, a metal layer is first oxidized to form a metal oxide layer and an underlying metal layer. The metal oxide layer is then reduced to form a surface metal layer and an underlying metal oxide layer. The surface metal layer is then removed to leave the underlying metal oxide layer and the underlying metal layer. Further, the oxidizing, reducing, and removing processes can be repeated to achieve a target etch depth. In addition, a target etch rate can also achieved for each process cycle of oxidizing, reducing, and removing.

Abstract: A method for selective plasma etching of silicon oxide relative to silicon nitride. The method includes a) providing a substrate containing a silicon oxide film and a silicon nitride film, b) exposing the substrate to a plasma-excited treatment gas containing 1) H2 and 2) HF, F2, or both HF and F2, to form a silicon oxide surface layer with reduced oxygen content on the silicon oxide film and form an ammonium salt layer on the silicon nitride film, c) exposing the substrate to a plasma-excited halogen-containing gas that reacts with and removes the silicon oxide surface layer from the silicon oxide film, and d) repeating steps b) and c) at least once to further selectively etch the silicon oxide film relative to the ammonium salt layer on the silicon nitride film. The ammonium salt layer may be removed when the desired etching has been achieved.