Abstract: After forming a material stack including, from bottom to top, a dielectric material layer, a transfer layer, a hard mask layer and a neutral layer over a substrate, the neutral layer and the hard mask layer is patterned to create trenches therein that correspond to areas where unnecessary lines generated by a self-assembly of a self-assembling material subsequently formed and/or unnecessary portions of such lines are present. The self-assembling material is applied over the top surfaces of the patterned neutral layer and the transfer layer to form a self-aligned lamellar structure including alternating first and second domains. The second domains are removed selective to the first domains to provide a directed self-assembly (DSA) pattern of the first domains. Portions of the first domains not intersecting the trenches can be transferred into the patterned hard mask layer, resulting in a composite pattern of a pattern of trenches and the DSA pattern.

Abstract: A method of fabricating a semiconductor device is disclosed. The method includes forming a first patterned hard mask over a material layer. The first patterned hard mask defines an opening. The method also includes forming a direct-self-assembly (DSA) layer having a first portion and a second portion within the opening, removing the first portion of the DSA layer, forming spacers along sidewalls of the second portion of the DSA layer and removing the second portion of the DSA layer. The spacers form a second patterned hard mask over the material layer.

Abstract: After forming spacers over a hard mask layer using a sidewall image transfer process, a neutral material layer is formed on the portions of the hard mask layer that are not covered by the spacers. The spacers and the neutral material layer guide the self-assembly of a block copolymer material. The microphase separation of the block copolymer material provides a lamella structure of alternating domains of the block copolymer material.

Abstract: Guiding pattern portions are formed on a surface of a lithographic material stack that is disposed on a surface of a semiconductor substrate. A copolymer layer is then formed between each neighboring pair of guiding pattern portions and thereafter a directed self-assembly process is performed that causes phase separation of the various polymeric domains of the copolymer layer. Each guiding pattern portion is selectively removed, followed by the removal of each first phase separated polymeric domain. Each second phase separated polymeric domain remains and is used as an etch mask in forming semiconductor fins in an upper semiconductor material portion of the semiconductor substrate.

Abstract: Block copolymers (BCPs) for self-assembly applications comprise a linear fluorinated linking group L? joining a pair of adjacent blocks. A film layer comprising a BCP, which is disposed on an underlayer and in contact with an atmosphere, is capable of forming a perpendicularly oriented domain pattern when the underlayer is preferentially wetted by one domain of an otherwise identical self-assembled BCP in which all fluorines of L? are replaced by hydrogen. The BCP can be a low-chi or high-chi BCP. In a preferred embodiment, the BCP comprises a styrene-based first block, and a second block comprises a carbonate and/or ester repeat unit formed by ring opening polymerization of a cyclic carbonate and/or cyclic ester monomer. The linking group L? has a lower surface energy than each of the polymer blocks.

Abstract: A film layer comprising a high-chi (?) block copolymer for self-assembly and a hexafluoroalcohol-containing surface active polymer (SAP) was prepared on a substrate surface that was neutral wetting to the domains of the self-assembled block copolymer. The block copolymer comprises at least one polycarbonate block and at least one other block (e.g., a substituted or unsubstituted styrene-based block). The film layer, whose top surface has contact with an atmosphere, self-assembles to form a lamellar or cylindrical domain pattern having perpendicular orientation with respect to the underlying surface. Other morphologies (e.g., islands and holes of height 1.0 Lo) were obtained with films lacking the SAP. The SAP is preferentially miscible with, and lowers the surface energy of, the domain comprising the polycarbonate block.

Abstract: After forming a material stack including, from bottom to top, a dielectric material layer, a transfer layer, a hard mask layer and a neutral layer over a substrate, the neutral layer and the hard mask layer is patterned to create trenches therein that correspond to areas where unnecessary lines generated by a self-assembly of a self-assembling material subsequently formed and/or unnecessary portions of such lines are present. The self-assembling material is applied over the top surfaces of the patterned neutral layer and the transfer layer to form a self-aligned lamellar structure including alternating first and second domains. The second domains are removed selective to the first domains to provide a directed self-assembly (DSA) pattern of the first domains. Portions of the first domains not intersecting the trenches can be transferred into the patterned hard mask layer, resulting in a composite pattern of a pattern of trenches and the DSA pattern.

Abstract: After forming spacers over a hard mask layer using a sidewall image transfer process, a neutral material layer is formed on the portions of the hard mask layer that are not covered by the spacers. The spacers and the neutral material layer guide the self-assembly of a block copolymer material. The microphase separation of the block copolymer material provides a lamella structure of alternating domains of the block copolymer material.

Abstract: A film layer comprising a high-chi (?) block copolymer for self-assembly and a hexafluoroalcohol-containing surface active polymer (SAP) was prepared on a substrate surface that was neutral wetting to the domains of the self-assembled block copolymer. The block copolymer comprises at least one polycarbonate block and at least one other block (e.g., a substituted or unsubstituted styrene-based block). The film layer, whose top surface has contact with an atmosphere, self-assembles to form a lamellar or cylindrical domain pattern having perpendicular orientation with respect to the underlying surface. Other morphologies (e.g., islands and holes of height 1.0Lo) were obtained with films lacking the SAP. The SAP is preferentially miscible with, and lowers the surface energy of, the domain comprising the polycarbonate block.

Abstract: A patterned photoresist is provided atop a substrate. A hardening agent is applied to the patterned photoresist to provide a polymeric coated patterned photoresist. The polymeric coated patterned photoresist is baked to provide a hardened photoresist, and subsequent the baking step, the polymeric coating is removed from the hardened photoresist by rinsing. The hardened photoresist can be removed anytime during the patterning of the substrate by an aqueous resist developer.

Abstract: Block polymers are formed by ring opening polymerization (ROP) of a cyclic carbonate monomer using a polymeric initiator for the ROP that comprises repeating functionalized ethylene units. The block polymers are free of, or substantially free of, any polymer having a chemical structure that does not comprise the polymer backbone of the polymeric initiator. The block polymers are capable of directed self-assembly.

Abstract: An orientation control layer (OCL) for self-assembly of block copolymers comprises a random copolymer comprising a first repeat unit having an ethylenic backbone functional group and a side chain aromatic ring, a second repeat unit comprising an ethylenic backbone functional group and a side chain polycarbonate, and a third repeat unit comprising an ethylenic backbone functional group and a side chain ester or amide bearing an active group capable of forming a covalent bond with a substrate surface (e.g., a silicon wafer). The OCLs are neutral wetting to block copolymers having a high Flory-Huggins interaction parameter chi (?) (“high-chi” block copolymers) such as a block copolymer comprising a polystyrene block and a polycarbonate block. The neutral OCL wetting properties allow for formation of lamellar domain patterns of the self-assembled high-chi block copolymers to be oriented perpendicular to the OCL surface.

Abstract: The disclosure provides methods for directed self-assembly (DSA) of a block co-polymer (BCP). In one embodiment, a method includes: forming an oxide spacer along each of a first sidewall and a second sidewall of a cavity in a semiconductor substrate; forming a neutral layer between the oxide spacers and along a bottom of the cavity; and removing the oxide spacers to expose the first and second sidewalls and a portion of the bottom of the cavity adjacent the first and second sidewalls.

Abstract: A film layer comprising a high-chi (?) block copolymer for self-assembly and a surface active polymer (SAP) was prepared on a substrate surface that was neutral wetting to the domains of the self-assembled block copolymer. The block copolymer comprises at least one polycarbonate block and at least one other block (e.g., a styrene-based block). The SAP comprises a hydrophobic fluorinated first repeat unit and a non-fluorinated second repeat unit bearing at least one pendent OH group present as an alcohol or acid (e.g., carboxylic acid). The film layer, whose top surface has contact with an atmosphere, self-assembles to form a lamellar or cylindrical domain pattern having perpendicular orientation with respect to the underlying surface. Other morphologies (e.g., islands and holes of height 1.0Lo) were obtained with films lacking the SAP. The SAP is preferentially miscible with, and lowers the surface energy of, the domain comprising the polycarbonate block.

Abstract: A method to generate chemo-epitaxy masks includes receiving a device pattern comprising a plurality of device geometries, wherein the device pattern conforms to chemo-epitaxy constraints, enlarging the device geometries along a width of the device geometries to provide enlarged device geometries, and using the enlarged device geometries to generate at least one chemo-epitaxy mask corresponding to the device pattern. The at least one chemo-epitaxy mask may include a neutral hard mask and one or more cut masks. The method may also include bridging device geometries that are within a selected distance along a length of the device geometries and merging device geometries that overlap. The method may also include filling break regions between the device geometries with a neutral fill pattern. A corresponding computer program product and computer system are also disclosed herein.

Abstract: A method to generate chemo-epitaxy masks includes receiving a device pattern comprising a plurality of device geometries, wherein the device pattern conforms to chemo-epitaxy constraints, enlarging the device geometries along a width of the device geometries to provide enlarged device geometries, and using the enlarged device geometries to generate at least one chemo-epitaxy mask corresponding to the device pattern. The at least one chemo-epitaxy mask may include a neutral hard mask and one or more cut masks. The method may also include bridging device geometries that are within a selected distance along a length of the device geometries and merging device geometries that overlap. The method may also include filling break regions between the device geometries with a neutral fill pattern. A corresponding computer program product and computer system are also disclosed herein.

Abstract: A polymer composition comprising: (C) at least 80 wt % of a multimodal high density polyethylene having a density of 940 kg/m3 or more; and (D) 1 to 14 wt % of a cyclic ethylene copolymer or cyclic propylene copolymer.

Abstract: Guiding pattern portions are formed on a surface of a lithographic material stack that is disposed on a surface of a semiconductor substrate. A copolymer layer is then formed between each neighboring pair of guiding pattern portions and thereafter a directed self-assembly process is performed that causes phase separation of the various polymeric domains of the copolymer layer. Each guiding pattern portion is selectively removed, followed by the removal of each first phase separated polymeric domain. Each second phase separated polymeric domain remains and is used as an etch mask in forming semiconductor fins in an upper semiconductor material portion of the semiconductor substrate.

Abstract: A patterned photoresist is provided atop a substrate. A hardening agent is applied to the patterned photoresist to provide a polymeric coated patterned photoresist. The polymeric coated patterned photoresist is baked to provide a hardened photoresist, and subsequent the baking step, the polymeric coating is removed from the hardened photoresist by rinsing. The hardened photoresist can be removed anytime during the patterning of the substrate by an aqueous resist developer.

Abstract: A film layer comprising a high-chi (?) block copolymer for self-assembly and a surface active polymer (SAP) was prepared on a substrate surface that was neutral wetting to the domains of the self-assembled block copolymer. The block copolymer comprises at least one polycarbonate block and at least one other block (e.g., a styrene-based block). The SAP comprises a hydrophobic fluorinated first repeat unit and a non-fluorinated second repeat unit bearing at least one pendent OH group present as an alcohol or acid (e.g., carboxylic acid). The film layer, whose top surface has contact with an atmosphere, self-assembles to form a lamellar or cylindrical domain pattern having perpendicular orientation with respect to the underlying surface. Other morphologies (e.g., islands and holes of height 1.0Lo) were obtained with films lacking the SAP. The SAP is preferentially miscible with, and lowers the surface energy of, the domain comprising the polycarbonate block.