A method includes providing a layered structure on a substrate, the layered structure including a bottom layer formed over the substrate, a hard mask layer formed over the bottom layer, a material layer formed over the hard mask layer, and a photoresist layer formed over the material layer, exposing the photoresist layer to a radiation source, developing the photoresist layer, where the developing removes portions of the photoresist layer and the material layer in a single step without substantially removing portions of the hard mask layer, and etching the hard mask layer using the photoresist layer as an etch mask. The material layer may include acidic moieties and/or acid-generating molecules. The material layer may also include photo-sensitive moieties and crosslinking agents.

A method includes providing a layered structure on a substrate, the layered structure including a bottom layer formed over the substrate, a hard mask layer formed over the bottom layer, a material layer formed over the hard mask layer, and a photoresist layer formed over the material layer, exposing the photoresist layer to a radiation source, developing the photoresist layer, where the developing removes portions of the photoresist layer and the material layer in a single step without substantially removing portions of the hard mask layer, and etching the hard mask layer using the photoresist layer as an etch mask. The material layer may include acidic moieties and/or acid-generating molecules. The material layer may also include photo-sensitive moieties and crosslinking agents.

A method of manufacturing semiconductor device includes forming a multilayer photoresist structure including a metal-containing photoresist over a substrate. The multilayer photoresist structure includes two or more metal-containing photoresist layers having different physical parameters. The metal-containing photoresist is a reaction product of a first precursor and a second precursor, and each layer of the multilayer photoresist structure is formed using different photoresist layer formation parameters. The different photoresist layer formation parameters are one or more selected from the group consisting of the first precursor, an amount of the first precursor, the second precursor, an amount of the second precursor, a length of time each photoresist layer formation operation, and heating conditions of the photoresist layers. The multilayer photoresist structure is selectively exposed to actinic radiation to form a latent pattern, and the latent pattern is developed by applying developer to the selectively exposed multilayer photoresist structure to form the pattern.

A method according to the present disclosure includes providing a substrate, depositing an underlayer over the substrate, depositing a photoresist layer over the underlayer, exposing a portion of the photoresist layer and a portion of the underlayer to a radiation source according to a pattern, baking the photoresist layer and underlayer, and developing the exposed portion of the photoresist layer to transfer the pattern to the photoresist layer. The underlayer includes a polymer backbone, a polarity switchable group, a cross-linkable group bonded to the polymer backbone, and photoacid generator. The polarity switchable group includes a first end group bonded to the polymer backbone, a second end group including fluorine, and an acid labile group bonded between the first end group and the second end group. The exposing decomposes the photoacid generator to generate an acidity moiety that detaches the second end group from the polymer backbone during the baking.

A method for patterning a substrate in which a patterned photoresist structure can be formed on the substrate, the patterned photoresist structure having a sidewall. A conformal layer of spacer material can be deposited on the sidewall. The patterned photoresist structure can then be removed from the substrate, leaving behind the spacer material. Then, the substrate can be directionally etched using the sidewall spacer as an etch mask to form the substrate having a target critical dimension.

A pattern forming method includes forming a resist film having a first region, a second region, and a third region, on a substrate, irradiating the first region with light or an energy ray in a first irradiation amount, and irradiating the second region with light or an energy ray in a second irradiation amount, the second irradiation amount being smaller than the first irradiation amount. The pattern forming method also includes dissolving the resist film of the first region by using first liquid, forming a coating film on a side surface of the resist film after the resist film of the first region is dissolved, and dissolving the third region by using second liquid that is different from the first liquid.

A digitally imageable, photopolymerizable relief precursor at least comprising, arranged one above another in the order stated, (A) a dimensionally stable carrier; (AH) optionally, an adhesion-promoting layer; (B) a relief-forming layer, at least comprising a crosslinkable elastomeric binder, a first ethylenically unsaturated monomer, and a photoinitiator; (C) at least one interlayer, at least comprising a first, non-radically crosslinkable elastic polymer; (D) a laser-ablatable mask layer, at least comprising a second, non-radically crosslinkable elastic polymer, a UVA light-absorbing material, and an IR light-absorbing material; and optionally (E) a removable cover layer; characterized in that the layer (C) and optionally the layer (D) comprise at least one second ethylenically unsaturated monomer.

Embodiments disclosed herein include methods of depositing a metal oxo photoresist using dry deposition processes. In an embodiment, the method comprises forming a first metal oxo film on the substrate with a first vapor phase process including a first metal precursor vapor and a first oxidant vapor, and forming a second metal oxo film over the first metal oxo film with a second vapor phase process including a second metal precursor vapor and a second oxidant vapor.

A method of patterning a substrate includes forming a multilayer photoresist stack on a substrate. The multilayer photoresist stack includes a first layer of a wet photoresist deposited by spin-on deposition, and a second layer of a dry photoresist deposited by vapor deposition. The first layer is positioned over the second layer. A first relief pattern is formed in the first layer by exposure to a first pattern of actinic radiation of a first wavelength and development of developable portions of the first layer using a first development process. The first relief pattern uncovers portions of the second layer. A multi-color layer of the first relief pattern is formed. The multi-color layer includes the wet photoresist and a third material that is different from the wet photoresist and the dry photoresist. A selective patterning process is executed for uncovered portions of one or two of the wet photoresist, the dry photoresist and the third material.

A method of patterning a substrate includes forming a multilayer photoresist stack on a substrate. The multilayer photoresist stack includes a dry photoresist layer, deposited by vapor deposition, over a wet photoresist layer deposited by spin-on deposition. A first relief pattern is formed in the wet photoresist layer by exposure to a first pattern of actinic radiation of a first wavelength and development of developable portions of the wet photoresist layer using a first development process. The first relief pattern uncovers portions of the dry photoresist layer. A second relief pattern is formed in the dry photoresist layer by exposure to a second pattern of actinic radiation of a second wavelength and development of developable portions of the dry photoresist layer using a second development process. The developable portions of the dry photoresist layer are defined by the second pattern of actinic radiation and the first relief pattern.