Abstract: A composition for use in selective modification of a base material surface includes a polymer having, at an end of a main chain or a side chain thereof, a group including a first functional group capable of forming a bond with a metal, and a solvent.

Abstract: A composition for film formation includes a polymer and a solvent. The polymer includes a first repeating unit, a second repeating unit, a third repeating unit, and a structural unit on at least one end of a main chain of the polymer. The first repeating unit includes a crosslinkable group. The second repeating unit differs from the first repeating unit. The third repeating unit differs from the first repeating unit and has higher polarity than polarity of the second repeating unit. The structural unit includes an interacting group capable of interacting with Si—OH, Si—H or Si—N.

Abstract: A composition for pattern formation includes a first polymer, a second polymer and a solvent. The first polymer includes: a first block including a first structural unit derived from a substituted or unsubstituted styrene; and a second block including a second structural unit other than the first structural unit. The second polymer includes: the first structural unit; and a group bonding to at least one end of a main chain thereof and including a polar group. The polar group is preferably a hydroxy group or a carboxyl group. A number average molecular weight of the second polymer is preferably no greater than 6,000. A mass ratio of the second polymer to the first polymer is preferably no less than 0.15 and no greater than 0.4. The solvent preferably comprises a compound comprising a hydroxyl group and an alkyl ester group.

Abstract: A pattern-forming method includes: forming a pattern on an upper face side of a substrate; applying a first composition to a sidewall of the pattern; forming a resin layer by applying a second composition to an inner face side of the sidewall of the pattern coated with the first composition; allowing the resin layer to separate into a plurality of phases; and removing at least one of the plurality of phases. The first composition contains a first polymer. The second composition contains a second polymer. The second polymer includes a first block having a first structural unit and a second block having a second structural unit. The polarity of the second structural unit is higher than the polarity of the first structural unit. Immediately before forming of the resin layer, a static contact angle ? (°) of water on the sidewall of the pattern satisfies inequality (1).

Abstract: A method for selectively modifying a base material surface, includes applying a composition on a surface of a base material to form a coating film. The coating film is heated. The base material includes a surface layer which includes a first region including silicon. The composition includes a first polymer and a solvent. The first polymer includes at an end of a main chain or a side chain thereof, a group including a first functional group capable of forming a bond with the silicon. The first region preferably contains a silicon oxide, a silicon nitride, or a silicon oxynitride. The base material preferably further includes a second region that is other than the first region and that contains a metal; and the method preferably further includes, after the heating, removing with a rinse agent a portion formed on the second region, of the coating film.

Abstract: A radiation-sensitive composition includes: a first polymer having a first structural unit that includes an acid-labile group; and a first compound including a metal cation and a first anion that is a conjugate base of an acid. The acid has a pKa of no greater than 0. The acid is preferably sulfonic acid, nitric acid, organic azinic acid, disulfonylimidic acid or a combination thereof. The first compound is preferably represented by formula (1). In the formula (1), M represents a metal cation; A represents the first anion; x is an integer of 1 to 6; R1 represents a ? ligand; and y is an integer of 0 to 5, and a sum: x+y is no greater than 6. The van der Waals volume of the acid is preferably no less than 2.5×10?28 m3.

Abstract: A composition for use in selective modification of a base material surface includes a polymer having, at an end of a main chain or a side chain thereof, a group including a first functional group capable of forming a bond with a metal, and a solvent.

Abstract: A method for selectively modifying a base material surface, includes applying a composition on a surface of a base material to form a coating film. The coating film is heated. The base material includes a surface layer which includes a first region including a metal. The composition includes a first polymer and a solvent. The first polymer includes at an end of a main chain or a side chain thereof, a group including a first functional group capable of forming a bond with the metal. It is preferred that the base material further includes a second region comprising substantially only a non-metal, and the method further includes, after the heating, removing with a rinse agent a portion formed on the second region, of the coating film. The metal is preferably a constituent of a metal substance, an alloy, an oxide, an electrically conductive nitride or a silicide.

Abstract: A pattern-forming method includes: forming a pattern on an upper face side of a substrate; applying a first composition to a sidewall of the pattern; forming a resin layer by applying a second composition to an inner face side of the sidewall of the pattern coated with the first composition; allowing the resin layer to separate into a plurality of phases; and removing at least one of the plurality of phases. The first composition contains a first polymer. The second composition contains a second polymer. The second polymer includes a first block having a first structural unit and a second block having a second structural unit. The polarity of the second structural unit is higher than the polarity of the first structural unit. Immediately before forming of the resin layer, a static contact angle ? (°) of water on the sidewall of the pattern satisfies inequality (1).

Abstract: A pattern-forming method includes applying a radiation-sensitive composition comprising a complex on a substrate to provide a film on the substrate. The film is exposed. The film exposed is developed. The complex includes: a metal-containing component that is a transition metal compound having a hydrolyzable group, a hydrolysis product of the transition metal compound having a hydrolyzable group, a hydrolytic condensation product of the transition metal compound having a hydrolyzable group, or a combination thereof; and an organic compound represented by formula (1). In the formula (1), R1 represents an organic group having a valency of n, n being an integer of 1 to 4. In a case where n is 1, X represents —COOH. In a case where n is 2 to 4, X represents —OH, —COOH, —NCO, —NHRa, —COORA or —CO—C(RL)2—CO—RA.

Abstract: A pattern-forming method includes forming a base pattern having recessed portions on a front face side of a substrate directly or via other layer. The recessed portions of the base pattern are filled with a first composition to form a filler layer. Phase separation of the filler layer is allowed to form a plurality of phases of the filler layer. A part of the plurality of phases of the filler layer is removed to form a miniaturized pattern. The forming of the base pattern includes: forming a resist pattern on the front face side of the substrate; forming a layer of a second polymer on lateral faces of the resist pattern; and forming a layer of a third polymer that differs from the second polymer on a surface of the substrate or on a surface of the other layer.

Abstract: A radiation-sensitive composition includes: a first polymer having a first structural unit that includes an acid-labile group; and a first compound including a metal cation and a first anion that is a conjugate base of an acid. The acid has a pKa of no greater than 0. The acid is preferably sulfonic acid, nitric acid, organic azinic acid, disulfonylimidic acid or a combination thereof. The first compound is preferably represented by formula (1). In the formula (1), M represents a metal cation; A represents the first anion; x is an integer of 1 to 6; R1 represents a ? ligand; and y is an integer of 0 to 5, and a sum: x+y is no greater than 6. The van der Waals volume of the acid is preferably no less than 2.5×10?28 m3.

Abstract: A radiation-sensitive composition includes particles and a solvent. The particles include a first component and a second component. The first component is a hydrolyzation product or a hydrolytic condensation product of a metal compound including a hydrolyzable group, or a combination thereof; and the second component is an organic acid, an anion of the organic acid, a first compound represented by formula (1), or a combination thereof. The organic acid and the first compound each have a molecular weight of no less than 120. In the formula (1), R1 represents an organic group having a valency of n; X represents an alcoholic hydroxyl group, —NCO or —NHRa, wherein Ra represents a hydrogen atom or a monovalent organic group; and n is an integer of 2 to 4.

Abstract: A pattern-forming method includes applying a radiation-sensitive composition on a substrate to provide a film on the substrate. The film is exposed. The film exposed is developed. The radiation-sensitive composition includes a metal-containing component that is a metal compound having a hydrolyzable group, a hydrolysis product of the metal compound having a hydrolyzable group, a hydrolytic condensation product of the metal compound having a hydrolyzable group, or a combination thereof. A content of a transition metal atom in the metal-containing component with respect to total metal atoms in the metal-containing component is no less than 50 atomic %.

Abstract: Provided is a radiation-sensitive composition superior in sensitivity. A radiation-sensitive composition incudes a metal oxide having a structural unit represented by formula (1), and a solvent. In the formula (1), M represents germanium, tin or lead; R1 represents a monovalent organic group having no greater than 30 carbon atoms which includes at least one of an electron attractive group and an unsaturated bond-containing group, and bonds to M via a carbon atom.

Abstract: A radiation-sensitive resin composition includes a polymer component having first, second and third structural units, and a radiation-sensitive acid generating component including first and second radiation-sensitive acid generating agents. The first structural unit includes a group represented by formula (1). The second structural unit includes a hydroxyl group bonded to an aromatic ring. The third structural unit includes an acid-labile group. A sulfonic acid generated by the first acid generating agent includes a carbon atom that is adjacent to a sulfo group, and a fluorine atom or monovalent fluorinated hydrocarbon group bonded to the carbon atom. A sulfonic acid generated by the second acid generating agent includes a carbon atom that is adjacent to a sulfo group, and a carbon atom that is adjacent to the carbon atom, wherein neither a fluorine atom nor a monovalent fluorinated hydrocarbon group is bonded to the carbon atoms.

Abstract: A composition for film formation includes a polymer and a solvent. The polymer includes a first repeating unit, a second repeating unit, a third repeating unit, and a structural unit on at least one end of a main chain of the polymer. The first repeating unit includes a crosslinkable group. The second repeating unit differs from the first repeating unit. The third repeating unit differs from the first repeating unit and has higher polarity than polarity of the second repeating unit. The structural unit includes an interacting group capable of interacting with Si—OH, Si—H or Si—N.

Abstract: A pattern-forming method includes forming a base pattern having recessed portions on a front face side of a substrate directly or via other layer. The recessed portions of the base pattern are filled with a first composition to form a filler layer. Phase separation of the filler layer is allowed to form a plurality of phases of the filler layer. A part of the plurality of phases of the filler layer is removed to form a miniaturized pattern. The forming of the base pattern includes: forming a resist pattern on the front face side of the substrate; forming a layer of a second polymer on lateral faces of the resist pattern; and forming a layer of a third polymer that differs from the second polymer on a surface of the substrate or on a surface of the other layer.

Abstract: A method for selectively modifying a base material surface, includes applying a composition on a surface of a base material to form a coating film. The coating film is heated. The base material includes a surface layer which includes a first region including a metal. The composition includes a first polymer and a solvent. The first polymer includes at an end of a main chain or a side chain thereof, a group including a first functional group capable of forming a bond with the metal. It is preferred that the base material further includes a second region comprising substantially only a non-metal, and the method further includes, after the heating, removing with a rinse agent a portion formed on the second region, of the coating film. The metal is preferably a constituent of a metal substance, an alloy, an oxide, an electrically conductive nitride or a silicide.

Abstract: A composition includes a first polymer and a solvent. The first polymer includes a first structural unit including a fluorine atom, and a group including a first functional group at an end of a main chain or a side chain of the first polymer. The first functional group is capable of forming a bond with a metal or a metalloid. The first structural unit preferably includes a fluorinated hydrocarbon group. The first structural unit is preferably derived from a (meth)acrylic ester containing a fluorine atom, or a styrene compound containing a fluorine atom. The first structural unit preferably contains 6 or more fluorine atoms.