Abstract: The disclosure herein describes methods for Photosensitized Chemically Amplified Resist Chemicals (PS-CAR) to pattern light sensitive films (e.g., photoresist on anti-reflective coatings) on a semiconductor substrate. In one embodiment, a two-step exposure process may generate higher acid concentration regions within a photoresist layer. The PS-CAR chemicals may include photoacid generators (PAGs) and photosensitizer elements that enhance the decomposition of the PAGs into acid. The first exposure may be a patterned EUV or UV exposure that generates an initial amount of acid and photosensitizer. The second exposure may be a non-EUV flood exposure that excites the photosensitizer which increases the acid generation rate where the photosensitizer is located in the film stack. The distribution of energy during the exposures may be optimized by using certain characteristics (e.g., thickness, index of refraction, doping) of the photoresist layer, an underlying layer, and/or an overlying layer.

Abstract: A patterning method is provided in which a light-sensitive layer is formed, and a target resolution is defined for a pattern to be formed in a target layer. Based on a reference dose and reference LWR that results from a single patterning exposure at an EUV wavelength, the target resolution and reference dose, the light-sensitive layer is subjected to at least two radiation exposures including an EUV patterning exposure at a dose selected to be less than the reference dose and within 15 mJ/cm2-200 mJ/cm2, and a flood exposure at a wavelength of 200 nm-420 nm and a dose of 0.5 J/cm2-20 J/cm2. The light-sensitive layer is then developed to form a mask pattern, which is used to etch the pattern into the target layer with the target resolution and a LWR less than or approximately equal to the reference LWR and ?5 nm.

Abstract: A method for critical dimension control in which a substrate is received having an underlying layer and a radiation-sensitive material layer thereon. The radiation-sensitive material is exposed through a patterned mask to a first wavelength of light in the UV spectrum, and developed a first time. The radiation-sensitive material is flood exposed to a second wavelength of light different from the first wavelength of light and developed a second time to form a pattern.

Abstract: The disclosure herein describes methods for Photosensitized Chemically Amplified Resist Chemicals (PS-CAR) to pattern light sensitive films on a semiconductor substrate. In one embodiment, a two-step exposure process may generate higher acid concentration regions within a photoresist layer. The PS-CAR chemicals may include photoacid generators (PAGs) and photosensitizer elements that enhance the decomposition of the PAGs into acid. The first exposure may be a patterned EUV exposure that generates an initial amount of acid and photosensitizer. The second exposure may be a non-EUV flood exposure that excites the photosensitizer which increases the acid generation rate where the photosensitizer is located on the substrate. The distribution of energy during the exposures may be optimized by using certain characteristics (e.g., thickness, index of refraction, doping) of the photoresist layer, an underlying layer, and/or an overlying layer.

Abstract: A method for critical dimension control in which a substrate is received having an underlying layer and a patterned layer formed on the underlying layer, the patterned layer including radiation-sensitive material and a pattern of varying elevation with a first critical dimension. The method further includes applying an overcoat layer over the patterned layer, the overcoat layer containing a photo agent selected from a photosensitizer generator compound, a photosensitizer compound, a photoacid generator compound, a photoactive agent, an acid-containing compound, or a combination of two or more thereof. The overcoat layer is then exposed to electromagnetic radiation, wherein the dose of electromagnetic radiation incident upon different exposed regions of the substrate is varied, and then the overcoat layer and patterned layer are heated. The method further includes developing the overcoat layer and the patterned layer to alter the first critical dimension of the patterned layer to a second critical dimension.

Abstract: A patterning method is provided in which a light-sensitive layer is formed, and a target resolution is defined for a pattern to be formed in a target layer. Based on a reference dose and reference LWR that results from a single patterning exposure at an EUV wavelength, the target resolution and reference dose, the light-sensitive layer is subjected to at least two radiation exposures including an EUV patterning exposure at a dose selected to be less than the reference dose and within 15 mJ/cm2-200 mJ/cm2, and a flood exposure at a wavelength of 200 nm-420 nm and a dose of 0.5 J/cm2-20 J/cm2. The light-sensitive layer is then developed to form a mask pattern, which is used to etch the pattern into the target layer with the target resolution and a LWR less than or approximately equal to the reference LWR and ?5 nm.

Abstract: A method for critical dimension control in which a substrate is received having an underlying layer and a patterned layer formed on the underlying layer, the patterned layer including radiation-sensitive material and a pattern of varying elevation with a first critical dimension. The method further includes applying an overcoat layer over the patterned layer, the overcoat layer containing a photo agent selected from a photosensitizer generator compound, a photosensitizer compound, a photoacid generator compound, a photoactive agent, an acid-containing compound, or a combination of two or more thereof. The overcoat layer is then exposed to electromagnetic radiation, wherein the dose of electromagnetic radiation incident upon different exposed regions of the substrate is varied, and then the overcoat layer and patterned layer are heated. The method further includes developing the overcoat layer and the patterned layer to alter the first critical dimension of the patterned layer to a second critical dimension.

Abstract: The disclosure herein describes methods for Photosensitized Chemically Amplified Resist Chemicals (PS-CAR) to pattern light sensitive films (e.g., photoresist on anti-reflective coatings) on a semiconductor substrate. In one embodiment, a two-step exposure process may generate higher acid concentration regions within a photoresist layer. The PS-CAR chemicals may include photoacid generators (PAGs) and photosensitizer elements that enhance the decomposition of the PAGs into acid. The first exposure may be a patterned EUV or UV exposure that generates an initial amount of acid and photosensitizer. The second exposure may be a non-EUV flood exposure that excites the photosensitizer which increases the acid generation rate where the photosensitizer is located in the film stack. The distribution of energy during the exposures may be optimized by using certain characteristics (e.g., thickness, index of refraction, doping) of the photoresist layer, an underlying layer, and/or an overlying layer.

Abstract: A method for critical dimension control in which a substrate is received having an underlying layer and a patterned layer formed on the underlying layer, the patterned layer including radiation-sensitive material and a pattern of varying elevation with a first critical dimension. The method further includes applying an overcoat layer over the patterned layer, the overcoat layer containing a photo agent selected from a photosensitizer generator compound, a photosensitizer compound, a photoacid generator compound, a photoactive agent, an acid-containing compound, or a combination of two or more thereof. The overcoat layer is then exposed to electromagnetic radiation, wherein the dose of electromagnetic radiation applied to different regions of the substrate is varied, and then the overcoat layer and patterned layer are heated. The method further includes developing the overcoat layer and the patterned layer to alter the first critical dimension of the patterned layer to a second critical dimension.

Abstract: The disclosure herein describes methods for Photosensitized Chemically Amplified Resist Chemicals (PS-CAR) to pattern light sensitive films (e.g., photoresist on anti-reflective coatings) on a semiconductor substrate. In one embodiment, a two-step exposure process may generate higher acid concentration regions within a photoresist layer. The PS-CAR chemicals may include photoacid generators (PAGs) and photosensitizer elements that enhance the decomposition of the PAGs into acid. The first exposure may be a patterned EUV or UV exposure that generates an initial amount of acid and photosensitizer. The second exposure may be a non-EUV flood exposure that excites the photosensitizer which increases the acid generation rate where the photosensitizer is located in the film stack. The distribution of energy during the exposures may be optimized by using certain characteristics (e.g., thickness, index of refraction, doping) of the photoresist layer, an underlying layer, and/or an overlying layer.

Abstract: A method for critical dimension control in which a substrate is received having an underlying layer and a patterned layer formed on the underlying layer, the patterned layer including radiation-sensitive material and a pattern of varying elevation with a first critical dimension. The method further includes applying an overcoat layer over the patterned layer, the overcoat layer containing a photo agent selected from a photosensitizer generator compound, a photosensitizer compound, a photoacid generator compound, a photoactive agent, an acid-containing compound, or a combination of two or more thereof. The overcoat layer is then exposed to electromagnetic radiation, wherein the dose of electromagnetic radiation applied to different regions of the substrate is varied, and then the overcoat layer and patterned layer are heated. The method further includes developing the overcoat layer and the patterned layer to alter the first critical dimension of the patterned layer to a second critical dimension.

Abstract: A method for critical dimension control in which a substrate is received having an underlying layer and a radiation-sensitive material layer thereon. The radiation-sensitive material is exposed through a patterned mask to a first wavelength of light in the UV spectrum, and developed a first time. The radiation-sensitive material is flood exposed to a second wavelength of light different from the first wavelength of light and developed a second time to form a pattern.

Abstract: A method and apparatus are disclosed for optimizing a rinsing and drying process in semiconductor manufacturing. The optimization seeks to maximize processing throughput while maintaining low defect counts and high device yields, and utilizes simulation and experimental data to set the optimal process parameters for the rinsing and drying process. Improved methods of rinse liquid and purge gas nozzle movement are also disclosed.

Abstract: A method for mitigating shot noise in extreme ultraviolet (EUV) lithography and patterning of photo-sensitized chemically-amplified resist (PS-CAR) is described. The method includes a first EUV patterned exposure to generate a photosensitizer and a second flood exposure at a wavelength different than the wavelength of the first EUV patterned exposure, to generate acid in regions exposed during the first EUV patterned exposure, wherein the photosensitizer acts to amplify acid generation and improve contrast. The resist may be exposed to heat, liquid solvent, solvent atmosphere, or a vacuum to mitigate the effects of EUV shot noise on photosensitizer concentration which may accrue during the first EUV patterned exposure.

Abstract: The disclosure herein describes methods for Photosensitized Chemically Amplified Resist Chemicals (PS-CAR) to pattern light sensitive films on a semiconductor substrate. In one embodiment, a two-step exposure process may generate higher acid concentration regions within a photoresist layer. The PS-CAR chemicals may include photoacid generators (PAGs) and photosensitizer elements that enhance the decomposition of the PAGs into acid. The first exposure may be a patterned EUV exposure that generates an initial amount of acid and photosensitizer. The second exposure may be a non-EUV flood exposure that excites the photosensitizer which increases the acid generation rate where the photosensitizer is located on the substrate. The distribution of energy during the exposures may be optimized by using certain characteristics (e.g., thickness, index of refraction, doping) of the photoresist layer, an underlying layer, and/or an overlying layer.

Abstract: The disclosure herein describes methods for Photosensitized Chemically Amplified Resist Chemicals (PS-CAR) to pattern light sensitive films on a semiconductor substrate. In one embodiment, a two-step exposure process may generate higher acid concentration regions within a photoresist layer. The PS-CAR chemicals may include photoacid generators (PAGs) and photosensitizer elements that enhance the decomposition of the PAGs into acid. The first exposure may be a patterned EUV exposure that generates an initial amount of acid and photosensitizer. The second exposure may be a non-EUV flood exposure that excites the photosensitizer which increases the acid generation rate where the photosensitizer is located on the substrate. The distribution of energy during the exposures may be optimized by using certain characteristics (e.g., thickness, index of refraction, doping) of the photoresist layer, an underlying layer, and/or an overlying layer.

Abstract: A method of patterning a layered substrate is provided that includes forming a layer of a block copolymer on a substrate, annealing the layer of the block copolymer to affect microphase segregation such that self-assembled domains are formed, and annealing the layer of the block copolymer a second time to refine or modify the microphase segregation, where one of the annealing steps uses an absorption based heating method.

Abstract: Methods for measuring photosensitizer concentrations in a photo-sensitized chemically-amplified resist (PS-CAR) patterning process are described. Measured photosensitizer concentrations can be used in feedback and feedforward control of the patterning process and subsequent processing steps. Also described is a metrology target formed using PS-CAR resist, and a substrate including a plurality of such metrology targets to facilitate patterning process control.

Abstract: Systems and methods for SOC planarization are described. In an embodiment, an apparatus for SOC planarization includes a substrate holder configured to support a microelectronic substrate. Additionally, the apparatus may include a light source configured to emit ultraviolet (UV) light toward a surface of the microelectronic substrate. In an embodiment, the apparatus may also include an isolation window disposed between the light source and the microelectronic substrate. Also, the apparatus may include a gas distribution unit configured to inject gas in a region between the isolation window and the microelectronic substrate. Furthermore, the apparatus may include an etchback leveling component configured to reduce non-uniformity of a UV light treatment of the microelectronic substrate.

Abstract: Methods and heat treatment apparatus for heating a substrate and any layer carried on the substrate during a bake process. A heat exchange gap between the substrate and a heated support is at least partially filled by a gas having a high thermal conductivity. The high thermal conductivity gas is introduced into the heat exchange gap by displacing a lower thermal conductivity originally present in the heat exchange gap when the substrate is loaded. Heat transfer across the heat exchange gap is mediated by the high thermal conductivity gas.