Abstract: A method for forming a pattern in a semiconductor device is disclosed which can increase the contact area between a photoresist and an anti-reflective film by performing an etching process on the anti-reflective film in a process of forming a photoresist pattern for a semiconductor device so as to form fine irregularities, thereby preventing collapse of a photoresist pattern. The disclosed method includes (a) forming an organic anti-reflective film by coating an organic anti-reflective coating composition onto an upper portion of a layer to be etched, and performing a baking process thereto; (b) forming fine irregularities on the organic anti-reflective film by performing an etching process on the formed organic anti-reflective film; and (c) forming a photoresist pattern by coating a photoresist on the upper portion of the organic anti-reflective film, exposing the photoresist and then developing the same.

Abstract: The present disclosure relates to an organic anti-reflective coating composition and a method for forming photoresist patterns using the same. The anti-reflective coating compositions are useful for preventing reflection of a lower film layer or a substrate of a photoresist film, reducing standing waves caused by light and variations in the thickness of the photoresist itself, and increasing the uniformity of the photoresist patterns. More particularly, the present invention relates to an organic anti-reflective coating composition comprising particular organo-silicon based polymers and a method for forming photoresist patterns using the same. The organic anti-reflective coating composition can prevent excessive absorbency of an anti-reflective film formed therefrom and, thus, minimize the reflectivity of the film so that it can efficiently remove standing waves and increase the uniformity of the photoresist pattern.

Abstract: A method for forming patterns of a semiconductor device is disclosed which inhibits collapse of photoresist patterns in photoresist pattern-forming processes of the semiconductor device by forming micro-bends in an anti-reflective film to increase the contact area between a photoresist and the anti-reflective film and, simultaneously prevents critical dimension (CD) alteration of the photoresist pattern by creating micro-bends and double-laminating of anti-reflective films with different refractive indices and light-absorbencies.

Abstract: Photoresist monomers, photoresist polymers prepared therefrom, and photoresist compositions using the polymers are disclosed. More specifically, photoresist polymers comprising a photoresist monomer containing fluorine-substituted benzylcarboxylate represented by Formula 1, and a composition comprising the polymer are disclosed. The photoresist composition has excellent etching resistance, heat resistance and adhesiveness, and can be developed in aqueous tetramethylammonium hydroxide (TMAH) solution. And, the present photoresist composition is suitable to form a fine pattern using deep ultraviolet light source such as VUV (157 nm), since the composition has low light absorbance at 193 nm and 157 nm wavelength. wherein, X1, X2, R1, l and m are defined in the specification.

Abstract: Photoresist polymers having nitro groups (—NO2), and photoresist compositions containing the same. A photoresist pattern having excellent endurance, etching resistance, reproducibility and resolution can be formed by the use of the photoresist copolymer comprising polymerization repeating units represented by Chemical Formula 1a or 1b: wherein, R1, a, b, c, d, e, f, g and h is defined in the specification. Having nitro groups in the polymer, the photoresist polymer results in a low absorbance in the range of 157 nm wavelength, so that it is extremely useful for a photolithography process using, in particular, VUV light source.

Abstract: A process of forming ultra fine patterns using bottom anti-reflective coating containing acid generator. More particularly, a process of forming vertical patterns using an organic bottom anti-reflective coating containing excessive amount of acid generator, in order to prevent formation of sloping patterns due to photoresist resins absorbing wavelength of light used as light sources during lithography process using light sources such as KrF, ArF, VUV, EUV, E-beam and ion beam, even when photoresist resins having high absorbance to light source are used.

Abstract: Cleaning solutions for removing photoresist resins and a method of forming patterns using the same are disclosed. The cleaning solution includes water (H2O) as main component, one or more surfactants as additive selected from the group consisting of polyoxyalkylene compounds, a salt of alcohol amine of Formula 1 and hydrocarbon compounds having carboxylic acid (—COOH) group, a salt of alcohol amine of Formula 1 and hydrocarbon compounds having sulfonic acid (—SO3H) group, polyethylene glycol compounds, compounds of Formula 3, compounds having a molecular weight ranging from 1000 to 10000 including repeating unit of Formula 4, polyether denatured silicon compounds and alcohol compounds.

Abstract: A hot plate oven used in a thermal process of forming an ultrafine photoresist pattern and a method of forming a pattern using the same. More particularly, a hot plate oven used to flow photoresist under the high pressure in the sealed oven during a resist flow process.

Abstract: Photoresist monomers, polymers thereof, photoresist compositions containing the same for preventing acid generated in the exposed area during the course of a photolithography process from being diffused to the unexposed area. The line edge roughness and slope pattern are improved when an ultrafine photoresist pattern is formed using photoresist copolymer having a multi-oxygen-containing compound as a repeating unit such as an ethyleneoxy moiety represented by Formula 1 with at least one polymerizable carbon-carbon double bond. In addition, the shape of pattern is improved by eliminating top loss and the adhesion of pattern to the substrate is improved.

Abstract: Cleaning solutions for removing photoresist materials and a method of forming underlying layer patterns of semiconductor devices using the same. The cleaning solutions for removing photoresist include a solvent mixture of H2O and an organic solvent, an amine compound, a transition metal-removing material and an alkali metal-removing material, and may further include a hydrazine hydrate.

Abstract: Photoresist additives for preventing the acid generated in the exposed area during the course of a photolithography process from being diffused to the unexposed area, photoresist compositions containing the same, and a process for forming a photoresist pattern using the same. Photoresist compositions comprising the disclosed additive can prevent acid diffusion effectively even if the additive is used in low concentrations, thereby improving LER, resulting in excellent profiles and lowering optimum irradiation energies.

Abstract: Cleaning solutions for removing photoresist resins remaining on the underlying layer patterns formed by photolithography process using the photoresist patterns as etching mask. The cleaning solution for removing photoresist comprises H2O as solvent, amine compounds, hydrazine hydrate, transition metal-removing material and alkali metal-removing material. Photoresist coated on the top portion of underlying layers can be rapidly and effectively removed by the disclosed cleaning solution. In addition, the cleaning solution is environment-friendly because H2O is used as the solvent, and has little effect on metal layers when underlying layers are formed of metals.

Abstract: Photoresist monomers of following Formula 1, photoresist polymers thereof, and photoresist compositions containing the same. The photoresist polymer includes a repeating unit comprising the photoresist monomer of Formula 1 as a comonomer and the photoresist composition containing the same have excellent etching resistance, heat resistance and adhesiveness to a wafer, and is developable in aqueous tetramethylammonium hydroxide (TMAH) solution. In addition, the photoresist composition has low light absorbance at 157 nm wavelength, and thus is suitable for a photolithography process using ultraviolet light sources such as VUV (157 nm) in fabricating a minute circuit for a high integration semiconductor device.

Abstract: Photoresist monomers of following Formula 1, photoresist polymers thereof, and photoresist compositions containing the same. The photoresist polymers include a repeating unit comprising the photoresist monomer of Formula 1 as a comonomer and the photoresist compositions containing the same have excellent etching resistance, heat resistance and adhesiveness to a wafer, and are developable in aqueous tetramethylammonium hydroxide (TMAH) solutions. In addition, the photoresist compositions have a low light absorbance at 157 nm wavelength, and thus are suitable for a photolithography process using ultraviolet light sources such as VUV (157 nm) in fabricating a minute circuit for a high integration semiconductor device.

Abstract: Photoresist monomers, photoresist polymers prepared therefrom, and photoresist compositions using the polymer are disclosed. The photoresist polymers include photoresist monomers containing fluorine-substituted benzylcarboxylate group represented by Formula 1. The photoresist composition has excellent etching resistance, heat resistance and adhesiveness, and is developable in aqueous tetramethylammonium hydroxide (TMAH) solution. As the composition has low light absorbance at 193 nm and 157 nm wavelength, it is suitable for a process using ultraviolet light source such as VUV (157 nm).

Abstract: Photoresist monomers, photoresist polymers prepared therefrom, and photoresist compositions using the polymers are disclosed. More specifically, photoresist polymers comprising a photoresist monomer containing fluorine-substituted benzylcarboxylate represented by Formula 1, and a composition comprising the polymer are disclosed. The photoresist composition has excellent etching resistance, heat resistance and adhesiveness, and can be developed in aqueous tetramethylammonium hydroxide (TMAH) solution. And, the present photoresist composition is suitable to form a fine pattern using deep ultraviolet light source such as VUV (157 nm), since the composition has low light absorbance at 193 nm and 157 nm wavelength.

Abstract: A chemical amplification photoresist monomer, a photoresist polymer prepared thereof, and a photoresist composition using the polymer. More specifically, a chemical amplification photoresist polymer comprising a fluorine-containing monomer represented by Chemical Formula 1, and a composition comprising the polymer.

Abstract: Photoresist monomers, photoresist polymers prepared thereof, and photoresist compositions using the polymer are disclosed. More specifically, photoresist polymers comprising maleimide monomer represented by Formula 1, and a composition comprising the polymer thereof are disclosed. The photoresist composition has excellent etching resistance, heat resistance and adhesiveness, and can be developed in an aqueous tetramethylammonium hydroxide (TMAH) solution. As the composition has low light absorbance at 193 nm and 157 nm wavelength, and it is suitable for a process using ultraviolet light source such as VUV (157 nm).

Abstract: Photoresist polymers having nitro groups (—NO2), and photoresist compositions containing the same.

Abstract: Photoresist monomers of following Formula 1, photoresist polymers thereof, and photoresist compositions containing the same. The photoresist composition has excellent etching resistance, heat resistance and adhesiveness to a wafer, and is developable in aqueous tetramethylammonium hydroxide (TMAH) solution. In addition, the photoresist composition has low light absorbance at 157 nm wavelength, and thus is suitable for a photolithography process using ultraviolet light sources such as VUV (157 nm) in fabricating a minute circuit for a high integration semiconductor device.