Methods for making thin-films on semiconductor substrates, may be patterned using EUV, include: depositing the organometallic polymer-like material onto the surface of the semiconductor substrate, exposing the surface to EUV to form a pattern, and developing the pattern for later transfer to underlying layers. The depositing operations may be performed by chemical vapor deposition (CVD), atomic layer deposition (ALD), and ALD with a CVD component, such as a discontinuous, ALD-like process in which metal precursors and counter-reactants are separated in either time or space.

Vacuum-integrated photoresist-less methods and apparatuses for forming metal hardmasks can provide sub-30 nm patterning resolution. A metal-containing (e.g., metal salt or organometallic compound) film that is sensitive to a patterning agent is deposited on a semiconductor substrate. The metal-containing film is then patterned directly (i.e., without the use of a photoresist) by exposure to the patterning agent in a vacuum ambient to form the metal mask. For example, the metal-containing film is photosensitive and the patterning is conducted using sub-30 nm wavelength optical lithography, such as EUV lithography.

Organometallic precursors are described for the formation of high resolution lithography patterning coatings based on metal oxide hydroxide chemistry. The precursor compositions generally comprise ligands readily hydrolysable by water vapor or other OH source composition under modest conditions. The organometallic precursors generally comprise a radiation sensitive organo ligand to tin that can result in a coating that can be effective for high resolution patterning at relatively low radiation doses and is particularly useful for EUV patterning. The precursors compositions are readily processable under commercially suitable conditions. Solution phase processing with in situ hydrolysis or vapor based deposition can be used to form the coatings.

Techniques described herein relate to methods, apparatus, and systems for promoting adhesion between a substrate and a metal-containing photoresist. For instance, the method may include receiving the substrate in a reaction chamber, the substrate having a first material exposed on its surface, the first material including a silicon-based material and/or a carbon-based material; generating a plasma from a plasma generation gas source that is substantially free of silicon, where the plasma includes chemical functional groups; exposing the substrate to the plasma to modify the surface of the substrate by forming bonds between the first material and chemical functional groups from the plasma; and depositing the metal-containing photoresist on the modified surface of the substrate, where the bonds between the first material and the chemical functional groups promote adhesion between the substrate and the metal-containing photoresist.

A method of forming a pattern in a photoresist layer includes forming a photoresist layer over a substrate, and reducing moisture or oxygen absorption characteristics of the photoresist layer. The photoresist layer is selectively exposed to actinic radiation to form a latent pattern, and the latent pattern is developed by applying a developer to the selectively exposed photoresist layer to form a pattern.

A method of operating a manufacturing platform includes moving a substrate through the manufacturing platform using one or more transfer modules. A dry resist is deposited on the substrate using a resist deposition module of the manufacturing platform. The substrate is examined for distortion with a metrology system that is part of a transfer module. The dry resist is exposed to UV or EUV radiation using an exposure tool of the manufacturing platform. Exposed or unexposed portions of the dry resist are removed using an etch module of the manufacturing platform.

A photoresist coating device includes a liquid vaporization module and a photoresist coating module. The liquid vaporization module is for converting a liquid photoresist into a gaseous photoresist and conveying the gaseous photoresist to a photoresist coating module. The photoresist coating module comprises a vapor coating unit, a cover plate and a carrying table, in which the vapor coating unit comprises a vapor channel and a vapor spray hole, in which the vapor spray hole is provided through the cover plate; the carrying table is for loading a substrate; and the cover plate is provided on a side of the carrying table close to the substrate. The vapor coating unit acquires the gaseous photoresist through the vapor channel and conveys the gaseous photoresist to a surface to be coated of the substrate on the carrying table through the vapor spray hole to form a photoresist coating.

A method for processing a substrate is described. The method includes forming a metal containing resist layer onto a substrate, patterning the metal containing resist layer, and performing a post exposure bake on the metal containing resist layer. The post exposure bake on the metal containing resist layer is a field guided post exposure bake operation and includes the use of an electric field to guide the ions or charged species within the metal containing resist layer. The field guided post exposure bake operation may be paired with a post development field guided bake operation.

A method of processing a substrate that includes: forming, over the substrate placed in a process chamber, an extreme ultraviolet (EUV)-active photoresist film including a tin alkenoxide moiety by exposing the substrate to a tin-containing precursor and exposing the substrate to an oxygen-containing precursor that reacts with the tin from the tin-containing precursor to form the tin alkenoxide; and patterning the EUV-active photoresist film by exposing the substrate to an EUV irradiation.

A process for plasmonic-based high resolution color printing is provided. The process includes a) providing a nanostructured substrate surface having a reverse structure geometry comprised of nanopits and nanoposts on a support, and b) forming a conformal continuous metal coating over the nanostructured substrate surface to generate a continuous metal film, the continuous metal film defining nanostructures for the plasmonic-based high resolution color printing, wherein a periodicity of the nanostructures is equal to or less than a diffraction limit of visible light. A nanostructured metal film or metal-film coated support obtained by the process and a method for generating a color image are also provided.