Abstract: A method for cleaning etch residues that may include treating an etched surface with an aqueous lanthanoid solution, wherein the aqueous lanthanoid solution removes an etch residue that includes a majority of hydrocarbons and at least one element selected from the group consisting of carbon, oxygen, fluorine, nitrogen and silicon. In one example, the aqueous solution may be cerium ammonium nitrate (Ce(NH4)(NO3)),(CAN).

Abstract: Cleaning solutions and processes for cleaning semiconductor devices or semiconductor tooling during manufacture thereof generally include contacting the semiconductor devices or semiconductor tooling with an acidic aqueous cleaning solution free of a fluorine containing compound, the acidic aqueous cleaning solution including at least one antioxidant and at least one non-oxidizing acid.

Abstract: A method for cleaning etch residues that may include treating an etched surface with an aqueous lanthanoid solution, wherein the aqueous lanthanoid solution removes an etch residue that includes a majority of hydrocarbons and at least one element selected from the group consisting of carbon, oxygen, fluorine, nitrogen and silicon. In one example, the aqueous solution may be cerium ammonium nitrate (Ce(NH4)(NO3)),(CAN).

Abstract: Cleaning solutions and processes for cleaning semiconductor devices or semiconductor tooling during manufacture thereof generally include contacting the semiconductor devices or semiconductor tooling with an acidic aqueous cleaning solution free of a fluorine containing compound, the acidic aqueous cleaning solution including at least one antioxidant and at least one non-oxidizing acid.

Abstract: A post metal chemical-mechanical planarization (CMP) cleaning process for advanced interconnect technology is provided. The process, which follows CMP, combines an acidic clean and a basic clean in sequence. The process can achieve a more than 60% reduction in CMP defects, such as polish residues, foreign materials, slurry abrasives, scratches, and hollow metal, relative to an all-basic clean process. The process also eliminates the circular ring defects that occur intermittently during roller brush cleans within a roller brush clean module.

Abstract: A post metal chemical-mechanical planarization (CMP) cleaning process for advanced interconnect technology is provided. The process, which follows CMP, combines an acidic clean and a basic clean in sequence. The process can achieve a more than 60% reduction in CMP defects, such as polish residues, foreign materials, slurry abrasives, scratches, and hollow metal, relative to an all-basic clean process. The process also eliminates the circular ring defects that occur intermittently during roller brush cleans within a roller brush clean module.

Abstract: Methods for removing a masking material, for example, a photoresist, and electronic devices formed by removing a masking material are presented. For example, a method for removing a masking material includes contacting the masking material with a solution comprising cerium. The cerium may be comprised in a salt. The salt may be cerium ammonium nitrate.

Abstract: Cleaning solutions and processes for cleaning semiconductor devices or semiconductor tooling during manufacture thereof generally include contacting the semiconductor devices or semiconductor tooling with an acidic aqueous cleaning solution free of a fluorine containing compound, the acidic aqueous cleaning solution including at least one antioxidant and at least one non-oxidizing acid.

Abstract: Cleaning processes for cleaning semiconductor devices or semiconductor tooling during manufacture thereof generally include contacting the semiconductor devices or semiconductor tooling with an antioxidant to form an insoluble adduct followed by solubilizing the adduct with a basic aqueous cleaning solution.

Abstract: An aqueous solution of a cerium (IV) complex or salt having an extended lifetime is provided. In one embodiment, the extended lifetime is achieved by adding at least one booster additive to an aqueous solution of the cerium (IV) complex or salt. In another embodiment, the extended lifetime is achieved by providing an aqueous solution of a cerium (IV) complex or salt and a cerium (III) complex or salt. The cerium (III) complex or salt can be added or it can be generated in-situ by introducing a reducing agent into the aqueous solution of the cerium (IV) complex or salt. The aqueous solution can be used to remove a mask material, especially an ion implanted and patterned photoresist, from a surface of a semiconductor substrate.

Abstract: A spin-on formulation that is useful in stripping an ion implanted photoresist is provided that includes an aqueous solution of a water soluble polymer containing at least one acidic functional group, and at least one lanthanide metal-containing oxidant. The spin-on formulation is applied to an ion implanted photoresist and baked to form a modified photoresist. The modified photoresist is soluble in aqueous, acid or organic solvents. As such one of the aforementioned solvents can be used to completely strip the ion implanted photoresist as well as any photoresist residue that may be present. A rinse step can follow the stripping of the modified photoresist.

Abstract: An organic planarizing layer (OPL) is formed atop a semiconductor substrate which includes a plurality of gate lines thereon. Each gate line includes at least a high k gate dielectric and a metal gate. A patterned photoresist having at least one pattern formed therein is then positioned atop the OPL. The at least one pattern in the photoresist is perpendicular to each of the gate lines. The pattern is then transferred by etching into the OPL and portions of each of the underlying gate lines to provide a plurality of gate stacks each including at least a high k gate dielectric portion and a metal gate portion. The patterned photoresist and the remaining OPL layer are then removed utilizing a sequence of steps including first contacting with a first acid, second contacting with an aqueous cerium-containing solution, and third contacting with a second acid.

Abstract: An organic planarizing layer (OPL) is formed atop a semiconductor substrate which includes a plurality of gate lines thereon. Each gate line includes at least a high k gate dielectric and a metal gate. A patterned photoresist having at least one pattern formed therein is then positioned atop the OPL. The at least one pattern in the photoresist is perpendicular to each of the gate lines. The pattern is then transferred by etching into the OPL and portions of each of the underlying gate lines to provide a plurality of gate stacks each including at least a high k gate dielectric portion and a metal gate portion. The patterned photoresist and the remaining OPL layer are then removed utilizing a sequence of steps including first contacting with a first acid, second contacting with an aqueous cerium-containing solution, and third contacting with a second acid.

Abstract: A spin-on formulation that is useful in stripping an ion implanted photoresist is provided that includes an aqueous solution of a water soluble polymer containing at least one acidic functional group, and at least one lanthanide metal-containing oxidant. The spin-on formulation is applied to an ion implanted photoresist and baked to form a modified photoresist. The modified photoresist is soluble in aqueous, acid or organic solvents. As such one of the aforementioned solvents can be used to completely strip the ion implanted photoresist as well as any photoresist residue that may be present. A rinse step can follow the stripping of the modified photoresist.

Abstract: A dielectric material layer is formed on a front surface of a photovoltaic device. A patterned PMMA-type-material-including layer is formed on the dielectric material layer, and the pattern is transferred into the top portion of the photovoltaic device to form trenches in which contact structures can be formed. In one embodiment, a blanket PMMA-type-material-including layer is deposited on the dielectric material layer, and is patterned by laser ablation that removes ablated portions of PMMA-type-material. The PMMA-type-material-including layer may also include a dye to enhance absorption of the laser beam. In another embodiment, a blanket PMMA-type-material-including layer may be deposited on the dielectric material layer and mechanically patterned to form channels therein. In yet another embodiment, a patterned PMMA-type-material-including layer is stamped on top of the dielectric material layer.

Abstract: An aqueous solution of a cerium (IV) complex or salt having an extended lifetime is provided. In one embodiment, the extended lifetime is achieved by adding at least one booster additive to an aqueous solution of the cerium (IV) complex or salt. In another embodiment, the extended lifetime is achieved by providing an aqueous solution of a cerium (IV) complex or salt and a cerium (III) complex or salt. The cerium (III) complex or salt can be added or it can be generated in-situ by introducing a reducing agent into the aqueous solution of the cerium (IV) complex or salt. The aqueous solution can be used to remove a mask material, especially an ion implanted and patterned photoresist, from a surface of a semiconductor substrate.

Abstract: An organic planarizing layer (OPL) is formed atop a semiconductor substrate which includes a plurality of gate lines thereon. Each gate line includes at least a high k gate dielectric and a metal gate. A patterned photoresist having at least one pattern formed therein is then positioned atop the OPL. The at least one pattern in the photoresist is perpendicular to each of the gate lines. The pattern is then transferred by etching into the OPL and portions of each of the underlying gate lines to provide a plurality of gate stacks each including at least a high k gate dielectric portion and a metal gate portion. The patterned photoresist and the remaining OPL layer are then removed utilizing a sequence of steps including first contacting with a first acid, second contacting with an aqueous cerium-containing solution, and third contacting with a second acid.

Abstract: Methods for removing a masking material, for example, a photoresist, and electronic devices formed by removing a masking material are presented. For example, a method for removing a masking material includes contacting the masking material with a solution comprising cerium. The cerium may be comprised in a salt. The salt may be cerium ammonium nitrate.

Abstract: A dielectric material layer is formed on a front surface of a photovoltaic device. A patterned PMMA-type-material-including layer is formed on the dielectric material layer, and the pattern is transferred into the top portion of the photovoltaic device to form trenches in which contact structures can be formed. In one embodiment, a blanket PMMA-type-material-including layer is deposited on the dielectric material layer, and is patterned by laser ablation that removes ablated portions of PMMA-type-material. The PMMA-type-material-including layer may also include a dye to enhance absorption of the laser beam. In another embodiment, a blanket PMMA-type-material-including layer may be deposited on the dielectric material layer and mechanically patterned to form channels therein. In yet another embodiment, a patterned PMMA-type-material-including layer is stamped on top of the dielectric material layer.

Abstract: The present invention discloses a composition suitable for use as a top antireflective coating and barrier layer for immersion lithography. The inventive composition is soluble in aqueous base solutions and insoluble in water. The inventive composition comprises a polymer having at least one hydrophobic moiety, at least one acidic moiety with a pKa of 1 or less, and at least one aqueous base soluble moiety. The present invention also discloses a method of forming a patterned layer on a substrate by using the inventive composition in lithography.