A pattern forming method in an embodiment includes forming, on or above a substrate, a block copolymer layer containing a first polymer and a second polymer having lower surface energy than the first polymer, heat treating the block copolymer layer to separate the block copolymer layer into a first phase containing the first polymer and a second phase containing the second polymer, and using an atomic layer deposition process, selectively forming a metal layer on the first phase and selectively removing the second phase.

A method of forming a pattern of a semiconductor device includes forming a lower film on a substrate having a first surface and a second surface at different levels, forming an upper film of hydrophobic material on the lower film, forming a block copolymer film on the upper film, phase-separating the block copolymer film to form first patterns spaced apart from one another and a second pattern spanning the first patterns and interposed between a bottom surface of each of the first patterns and the upper film, removing the first patterns, and performing an etch process using the second pattern or a residual part of the second pattern as an etch mask.

According to one embodiment, a pattern formation method includes forming a resist pattern on an underlying film, slimming the resist pattern, forming a pinning portion having affinity for a first polymer by depositing, on a surface of the slimmed resist pattern, an etching product produced by etching the underlying film, forming a neutral, film having affinity for the first polymer and a second polymer on the underlying film after the etching, forming a block copolymer film containing the first polymer and the second polymer on the pinning portion and the neutral film, forming a microphase separation pattern by applying a predetermined process to the block copolymer film to perform microphase separation.

A self-organization material according to an embodiment includes a block copolymer and a top coat material. The block copolymer contains a first block and a second block. The second block has a surface free energy higher than that of the first block. The top coat material contains a first portion having a surface free energy higher than that of the first block and lower than that of the second block, and a second portion having a surface free energy lower than that of the first block. The first portion is one of a homopolymer miscible with both the first block and the second block, and a random copolymer having a repeating unit of the first block and a repeating unit of the second block. The second portion is one of an organic siloxane-containing polymer and a fluorine-containing polymer.

According to one embodiment, a pattern forming method includes forming a resist pattern on an under-layer, forming a recessed portion in the under-layer by etching the under-layer using the resist pattern as a mask, slimming the resist pattern, forming a neutral layer having an affinity for first and second polymers on a region of the under-layer not covered with the slimmed resist pattern, forming a block copolymer film containing the first polymer and the second polymer on the slimmed resist pattern and the neutral layer, and forming a microphase separation pattern comprising a first portion formed of the first polymer and a second portion formed of the second polymer by applying microphase separation processing to the block copolymer film.

Provided herein are methods of directed self-assembly (DSA) on atomic layer chemical patterns and related compositions. The atomic layer chemical patterns may be formed from two-dimensional materials such as graphene. The atomic layer chemical patterns provide high resolution, low defect directed self-assembly. For example, DSA on a graphene pattern can be used achieve ten times the resolution of DSA that is achievable on a three-dimensional pattern such as a polymer brush. Assembly of block copolymers on the atomic layer chemical patterns may also facilitate subsequent etch, as the atomic layer chemical patterns are easier to etch than conventional pattern materials.

Disclosed herein is a method for manufacturing a patterned object and a light irradiation apparatus that make it possible to form a pattern that accurately follows a mask pattern with higher accuracy in a patterning process of irradiating a pattern forming substrate with vacuum ultra violet light. The light irradiation apparatus includes a mask stage arranged apart from the pattern forming substrate and configured to hold a mask on which a prescribed pattern is formed, and a vacuum ultra violet light source unit configured to irradiate the pattern forming substrate with vacuum ultra violet light through the mask. A space between the mask and the pattern forming substrate is set to be an atmosphere containing oxygen. The vacuum ultra violet light source unit irradiates light, as the vacuum ultra violet light, having a continuous spectrum in a range where a wavelength ranges from 180 nm to 200 nm.

Block copolymers and methods of making patterns of organic thin films using the block copolymers. The block copolymers comprise a fluorinated block. Thin films of the block copolymers have microdomains that can be aligned. As a result the patterns of organic thin films having smaller dimensions than the pattern of incident deep-UV or e-beam radiation can be formed. For example, the block copolymers can be used in lithography, filtration, and templating applications.

Provided are a transparent substrate having a nano pattern, and a method of manufacturing the same, which enables the nano pattern to be easily formed on the transparent substrate and has the nano pattern applicable to a large sized substrate by forming a resin layer made of transparent material on a transparent substrate; forming at least one or more unit pattern parts composed of a first pattern area and a second pattern area in which a plurality of grid patterns are formed, and a protrusion pattern formed between the first pattern area and the second pattern area, on the resin layer; and forming a nanoscale metal layer on the protrusion pattern.

A method for making patterns on a substrate, includes forming an assembly guide on first and second areas of the substrate, the assembly guide having, compared to a reference surface, openings with an opening ratio in the first area greater than that of the second area; depositing a block copolymer layer on the substrate to entirely fill the assembly guide and form an over-thickness on the reference surface; assembling the block copolymer, resulting in an organised portion of the block copolymer layer inside the openings; thinning uniformly the block copolymer layer, until a thickness corresponding to the organised portion of the block copolymer layer is reached; eliminating one of the phases of the assembled block copolymer, resulting in a plurality of initial patterns extending into the layer of block copolymer; and transferring the initial patterns of the block copolymer layer into the substrate to form the final patterns.