Abstract: Provided is a method for developing positive-tone chemically amplified resists with an organic developer solvent having at least one polyhydric alcohol, such as ethylene glycol and/or glycerol, alone or in combination with an additional organic solvent, such as isopropyl alcohol, and/or water. The organic solvent developed positive tone resists described herein are useful for lithography pattern forming processes; for producing semiconductor devices, such as integrated circuits (IC); and for applications where basic solvents are not suitable, such as the fabrication of chips patterned with arrays of biomolecules or deprotection applications that do not require the presence of acid moieties.

Abstract: Methods are disclosed for forming a layered structure comprising a self-assembled material. An initial patterned photoresist layer is treated photochemically, thermally, and/or chemically to form a treated patterned photoresist layer comprising a non-crosslinked treated photoresist. The treated photoresist is insoluble in an organic solvent suitable for casting a material capable of self-assembly. A solution comprising the material capable of self-assembly dissolved in the organic solvent is casted on the treated layer, and the organic solvent is removed. The casted material is allowed to self-assemble with optional heating and/or annealing, thereby forming the layered structure comprising the self-assembled material. The treated photoresist can be removed using an aqueous base and/or a second organic solvent.

Abstract: A method of forming a layered structure comprising a domain pattern of a self-assembled material utilizes a negative-tone patterned photoresist layer comprising non-crosslinked developed photoresist. The developed photoresist is not soluble in an organic casting solvent for a material capable of self-assembly. The developed photoresist is soluble in an aqueous alkaline developer and/or a second organic solvent. A solution comprising the material capable of self-assembly and the organic casting solvent is casted on the patterned photoresist layer. Upon removal of the organic casting solvent, the material self-assembles, thereby forming the layered structure.

Abstract: Provided is a method for developing positive-tone chemically amplified resists with an organic developer solvent having at least one polyhydric alcohol, such as ethylene glycol and/or glycerol, alone or in combination with an additional organic solvent, such as isopropyl alcohol, and/or water. The organic solvent developed positive tone resists described herein are useful for lithography pattern forming processes; for producing semiconductor devices, such as integrated circuits (IC); and for applications where basic solvents are not suitable, such as the fabrication of chips patterned with arrays of biomolecules or deprotection applications that do not require the presence of acid moieties.

Abstract: A layered structure comprising a self-assembled material is formed by a method that includes forming a photochemically, thermally and/or chemically treated patterned photoresist layer disposed on a first surface of a substrate. The treated patterned photoresist layer comprises a non-crosslinked treated photoresist. An orientation control material is cast on the treated patterned photoresist layer, forming a layer containing orientation control material bound to a second surface of the substrate. The treated photoresist and, optionally, any non-bound orientation control material are removed by a development process, resulting in a pre-pattern for self-assembly. A material capable of self-assembly is cast on the pre-pattern. The casted material is allowed to self-assemble with optional heating and/or annealing to produce the layered structure.

Abstract: Provided are novel symmetrical and asymmetrical bifunctional photodecomposable bases (PDBs) with dicarboxylate anion groups that show increased imaging performance. Also provided are photoresist compositions prepared with the bifunctional dicarboxylated PDBs and lithography methods that use the photoresist compositions of the present invention.

Abstract: Phenolic molecular glasses such as calixarenes include at least one fluoroalcohol containing unit. The fluoroalcohol containing molecular glasses can be used in photoresist compositions. Also disclosed are processes for generating a resist image on a substrate using the photoresist composition.

Abstract: Provided are novel symmetrical and asymmetrical bifunctional photodecomposable bases (PDBs) with dicarboxylate anion groups that show increased imaging performance. Also provided are photoresist compositions prepared with the bifunctional dicarboxylated PDBs and lithography methods that use the photoresist compositions of the present invention.

Abstract: Lithographic patterning methods involve the formation of a (one or more) metal oxide capping layer, which is rinsed with an aqueous alkaline solution as part of the method. The rinse solution does not damage the capping layer, but rather allows for lithographic processing without thinning the capping layer or introducing defects into it. Ammoniated water is a preferred rinse solution, which advantageously leaves behind no nonvolatile residue.

Abstract: An interconnection between a sublithographic-pitched structure and a lithographic pitched structure is formed. A plurality of conductive lines having a sublithographic pitch may be lithographically patterned and cut along a line at an angle less than 45 degrees from the lengthwise direction of the plurality of conductive lines. Alternately, a copolymer mixed with homopolymer may be placed into a recessed area and self-aligned to form a plurality of conductive lines having a sublithographic pitch in the constant width region and a lithographic dimension between adjacent lines at a trapezoidal region. Yet alternately, a first plurality of conductive lines with the sublithographic pitch and a second plurality of conductive lines with the lithographic pitch may be formed at the same level or at different.

Abstract: Disclosed are methods of forming polymer structures comprising: applying a solution of a block copolymer assembly comprising at least one block copolymer to a neutral substrate having a chemical pattern thereon, the chemical pattern comprising alternating pinning and neutral regions that are chemically distinct and have a first spatial frequency given by the number of paired sets of pinning and neutral regions along a given direction on the substrate; and forming domains of the block copolymer that form by lateral segregation of the blocks in accordance with the underlying chemical pattern, wherein at least one domain of the block copolymer assembly has an affinity for the pinning regions, wherein a structure extending across the chemical pattern is produced, the structure having a uniform second spatial frequency given by the number of repeating sets of domains along the given direction that is at least twice that of the first spatial frequency.

Abstract: Phenolic molecular glasses such as calixarenes include at least one fluoroalcohol containing unit. The fluoroalcohol containing molecular glasses can be used in photoresist compositions. Also disclosed are processes for generating a resist image on a substrate using the photoresist composition.

Abstract: A method of forming a layered structure comprising a domain pattern of a self-assembled material comprises: disposing on a substrate a photoresist layer comprising a non-crosslinking photoresist; optionally baking the photoresist layer; pattern-wise exposing the photoresist layer to first radiation; optionally baking the exposed photoresist layer; and developing the exposed photoresist layer with a non-alkaline developer to form a negative-tone patterned photoresist layer comprising non-crosslinked developed photoresist; wherein the developed photoresist is not soluble in a given organic solvent suitable for casting a given material capable of self-assembly, and the developed photoresist is soluble in an aqueous alkaline developer and/or a second organic solvent. A solution comprising the given material capable of self-assembly dissolved in the given organic solvent is casted on the patterned photoresist layer, and the given organic solvent is removed.

Abstract: Methods are disclosed for forming a layered structure comprising a self-assembled material. A method comprises disposing a photoresist layer comprising a non-crosslinking, positive-tone photoresist on a surface of a substrate; optionally baking the photoresist layer; pattern-wise exposing the photoresist layer to first radiation; optionally baking the exposed photoresist layer; developing the exposed photoresist layer with an aqueous alkaline developer to form an initial patterned photoresist layer. The initial patterned photoresist layer is treated photochemically, thermally, and/or chemically to form a treated patterned photoresist layer comprising non-crosslinked treated photoresist, wherein the treated photoresist is insoluble in a given organic solvent suitable for casting a given material capable of self-assembly, and the treated photoresist is soluble in the aqueous alkaline developer and/or a second organic solvent.

Abstract: A method of forming a layered structure comprising a self-assembled material comprises: disposing a non-crosslinking photoresist layer on a substrate; pattern-wise exposing the photoresist layer to first radiation; optionally heating the exposed photoresist layer; developing the exposed photoresist layer in a first development process with an aqueous alkaline developer, forming an initial patterned photoresist layer; treating the initial patterned photoresist layer photochemically, thermally and/or chemically, thereby forming a treated patterned photoresist layer comprising non-crosslinked treated photoresist disposed on a first substrate surface; casting a solution of an orientation control material in a first solvent on the treated patterned photoresist layer, and removing the first solvent, forming an orientation control layer; heating the orientation control layer to effectively bind a portion of the orientation control material to a second substrate surface; removing at least a portion of the treated pho

Abstract: Lithographic patterning methods involve the formation of a (one or more) metal oxide capping layer, which is rinsed with an aqueous alkaline solution as part of the method. The rinse solution does not damage the capping layer, but rather allows for lithographic processing without thinning the capping layer or introducing defects into it. Ammoniated water is a preferred rinse solution, which advantageously leaves behind no nonvolatile residue.

Abstract: An interconnection between a sublithographic-pitched structure and a lithographic pitched structure is formed. A plurality of conductive lines having a sublithographic pitch may be lithographically patterned and cut along a line at an angle less than 45 degrees from the lengthwise direction of the plurality of conductive lines. Alternately, a copolymer mixed with homopolymer may be placed into a recessed area and self-aligned to form a plurality of conductive lines having a sublithographic pitch in the constant width region and a lithographic dimension between adjacent lines at a trapezoidal region. Yet alternately, a first plurality of conductive lines with the sublithographic pitch and a second plurality of conductive lines with the lithographic pitch may be formed at the same level or at different.

Abstract: Disclosed are methods of forming polymer structures comprising: applying a solution of a block copolymer assembly comprising at least one block copolymer to a neutral substrate having a chemical pattern thereon, the chemical pattern comprising alternating pinning and neutral regions that are chemically distinct and have a first spatial frequency given by the number of paired sets of pinning and neutral regions along a given direction on the substrate; and forming domains of the block copolymer that form by lateral segregation of the blocks in accordance with the underlying chemical pattern, wherein at least one domain of the block copolymer assembly has an affinity for the pinning regions, wherein a structure extending across the chemical pattern is produced, the structure having a uniform second spatial frequency given by the number of repeating sets of domains along the given direction that is at least twice that of the first spatial frequency.

Abstract: Disclosed herein is a method of forming polymer structures comprising applying a solution of a diblock copolymer assembly comprising at least one diblock copolymer that forms lamellae, to a neutral surface of a substrate having a chemical pattern thereon, the chemical pattern comprising alternating pinning and neutral regions that are chemically distinct and which have a chemical pattern spatial frequency given by the number of paired sets of pinning and neutral regions along a given direction on the substrate; and forming domains comprising blocks of the diblock copolymer. The domains form by lateral segregation of the blocks. At least one domain has an affinity for the pinning regions and forms on the pinning region, the domains so formed on the pinning region are aligned with the underlying chemical pattern, and domains that do not form on the pinning region form adjacent to and are aligned with the domains formed on the pinning regions.

Abstract: A method and system is provided for computing lithographic images that may take into account non-scalar effects such as lens birefringence, resist stack effects, tailored source polarizations, and blur effects of the mask and the resist. A generalized bilinear kernel is formed, which is independent of the mask transmission function, and which may then be treated using a decomposition to allow rapid computation of an image that includes such non-scalar effects. Weighted pre-images may be formed from a coherent sum of pre-computed convolutions of the dominant eigenfunctions of the generalized bilinear kernel with the appropriate mask polygon sectors. The image at a point may be formed from the incoherent sum of the weighted pre-images over all of the dominant eigenfunctions of the generalized bilinear kernel. The resulting image can then be used to perform model-based optical proximity correction (MBOPC).