Abstract: A liquid removal composition and process for removing sacrificial anti-reflective coating (SARC) material from a substrate having same thereon. The liquid removal composition includes at least one fluoride-containing compound, at least one organic solvent, optionally water, and optionally at least one chelating agent. The composition achieves at least partial removal of SARC material in the manufacture of integrated circuitry with minimal etching of metal species on the substrate, such as aluminum, copper and cobalt alloys, and without damage to low-k dielectric materials employed in the semiconductor architecture.

Abstract: Disclosed herein is a composition and method for semiconductor processing. In one embodiment, a wet-cleaning composition for removal of photoresist is provided. The composition comprises a strong base; an oxidant; and a polar solvent. In another embodiment, a method for removing photoresist is provided. The method comprises the steps of applying a wet-cleaning composition comprising about 0.1 to about 30 weight percent strong base; about one to about 30 weight percent oxidant; about 20 to about 95 weight percent polar solvent; and removing the photoresist.

Abstract: Disclosed herein is a composition and method for semiconductor processing. In one embodiment, a wet-cleaning composition for removal of photoresist is provided. The composition comprises a strong base; an oxidant; and a polar solvent. In another embodiment, a method for removing photoresist is provided. The method comprises the steps of applying a wet-cleaning composition comprising about 0.1 to about 30 weight percent strong base; about one to about 30 weight percent oxidant; about 20 to about 95 weight percent polar solvent; and removing the photoresist.

Abstract: A liquid removal composition and process for removing sacrificial anti-reflective coating (SARC) material from a substrate having same thereon. The liquid removal composition includes at least one fluoride-containing compound, at least one organic solvent, optionally water, and optionally at least one chelating agent. The composition achieves at least partial removal of SARC material in the manufacture of integrated circuitry with minimal etching of metal species on the substrate, such as aluminum, copper and cobalt alloys, and without damage to low-k dielectric materials employed in the semiconductor architecture.

Abstract: A liquid removal composition and process for removing sacrificial anti-reflective coating (SARC) material from a substrate having same thereon. The liquid removal composition includes at least one fluoride-containing compound, at least one organic solvent, optionally water, and optionally at least one chelating agent. The composition achieves at least partial removal of SARC material in the manufacture of integrated circuitry with minimal etching of metal species on the substrate, such as aluminum, copper and cobalt alloys, and without damage to low-k dielectric materials employed in the semiconductor architecture.

Abstract: Disclosed herein is a composition and method for semiconductor processing. In one embodiment, a wet-cleaning composition for removal of photoresist is provided. The composition comprises a strong base; an oxidant; and a polar solvent. In another embodiment, a method for removing photoresist is provided. The method comprises the steps of applying a wet-cleaning composition comprising about 0.1 to about 30 weight percent strong base; about one to about 30 weight percent oxidant; about 20 to about 95 weight percent polar solvent; and removing the photoresist.

Abstract: Disclosed herein is a composition and method for semiconductor processing. In one embodiment, a wet-cleaning composition for removal of photoresist is provided. The composition comprises a strong base; an oxidant; and a polar solvent. In another embodiment, a method for removing photoresist is provided. The method comprises the steps of applying a wet-cleaning composition comprising about 0.1 to about 30 weight percent strong base; about one to about 30 weight percent oxidant; about 20 to about 95 weight percent polar solvent; and removing the photoresist.

Abstract: A composition and process for removing photoresist and/or sacrificial anti-reflective coating (SARC) materials from a substrate having such material(s) thereon. The composition includes a base component, such as a quaternary ammonium base in combination with an alkali or alkaline earth base, or alternatively a strong base in combination with an oxidant. The composition may be utilized in aqueous medium, e.g., with chelator, surfactant, and/or co-solvent species, to achieve high-efficiency removal of photoresist and/or SARC materials in the manufacture of integrated circuitry, without adverse effect on metal species on the substrate, such as copper, aluminum and/or cobalt alloys, and without damage to SiOC-based dielectric materials employed in the semiconductor architecture.

Abstract: Disclosed herein is a composition and method for semiconductor processing. In one embodiment, a wet-cleaning composition for removal of photoresist is provided. The composition comprises a strong base; an oxidant; and a polar solvent. In another embodiment, a method for removing photoresist is provided. The method comprises the steps of applying a wet-cleaning composition comprising about 0.1 to about 30 weight percent strong base; about one to about 30 weight percent oxidant; about 20 to about 95 weight percent polar solvent; and removing the photoresist.

Abstract: A liquid removal composition and process for removing photoresist and/or sacrificial anti-reflective coating (SARC) material from a microelectronic device having same thereon. The liquid removal composition includes at least one organic quaternary base and at least one surface interaction enhancing additive. The composition achieves at least partial removal of photoresist and/or SARC material in the manufacture of integrated circuitry with minimal etching of metal species on the microelectronic device, such as copper and cobalt, and without damage to low-k dielectric materials employed in the microelectronic device architecture.

Abstract: An aqueous-based composition and process for removing hardened photoresist and/or bottom anti-reflective coating (BARC) material from a microelectronic device having same thereon. The aqueous-based composition includes at least one chaotropic solute, at least one alkaline base, and deionized water. The composition achieves high-efficiency removal of hardened photoresist and/or BARC material in the manufacture of integrated circuitry without adverse effect to metal species on the substrate, such as copper, and without damage to low-k dielectric materials employed in the microelectronic device architecture.

Abstract: An aqueous-based composition and process for removing hardened photoresist and/or bottom anti-reflective coating (BARC) material from a microelectronic device having same thereon. The aqueous-based composition includes at least one chaotropic solute, at least one alkaline base, and deionized water. The composition achieves high-efficiency removal of hardened photoresist and/or BARC material in the manufacture of integrated circuitry without adverse effect to metal species on the substrate, such as copper, and without damage to low-k dielectric materials employed in the microelectronic device architecture.

Abstract: A liquid removal composition and process for removing photoresist and/or sacrificial anti-reflective coating (SARC) material from a microelectronic device having same thereon. The liquid removal composition includes at least one organic quaternary base and at least one surface interaction enhancing additive. The composition achieves at least partial removal of photoresist and/or SARC material in the manufacture of integrated circuitry with minimal etching of metal species on the microelectronic device, such as copper and cobalt, and without damage to low-k dielectric materials employed in the microelectronic device architecture.

Abstract: A liquid removal composition and process for removing sacrificial anti-reflective coating (SARC) material from a substrate having same thereon. The liquid removal composition includes at least one fluoride-containing compound, at least one organic solvent, optionally water, and optionally at least one chelating agent. The composition achieves at least partial removal of SARC material in the manufacture of integrated circuitry with minimal etching of metal species on the substrate, such as aluminum, copper and cobalt alloys, and without damage to low-k dielectric materials employed in the semiconductor architecture.