Abstract: A multiple patterning process employs a phase change material, portions of which can be converted to an amorphous state and then a remaining portion is selectively removed to provide high resolution pattern features with a feature spacing smaller than, for example, a minimum spacing available in a conventional patterning layer employing a single exposure. A lithographic apparatus for use in the process may comprise an exposure tool having a single illuminator and single patterning device that is imaged through a single exposure slit onto a scanning substrate. Alternatively, the exposure tool may have multiple illuminators and/or multiple scanning complementary patterning devices optionally used with multiple exposure slits on the scanning substrate to facilitate double patterning in a single substrate pass.

Abstract: A maskless pattern generating system for use in lithographic processing includes a liquid crystal pixel array. The system generates a light beam and applies a voltage level to each pixel of the pixel array to modulate a polarization state of the light beam so as to create a pattern image. The voltage levels correspond to greyscale levels assigned to the pixels. The system can receive a control signal input based on pattern information that defines the pattern image. The setting of the individual voltage levels can allow the liquid crystal pixel array to act as a phase shift mask, can allow the pattern image to be shifted, and can allow the manipulation of a pattern image edge. This maskless pattern writing system acts as a light valve to control pattern imagery, on a pixel by pixel basis, for the purposes of direct writing patterns.

Abstract: An immersion lithography apparatus is provided that includes an energy source, a projection optical system, a stage, a showerhead including an immersion liquid supply device and an immersion liquid discharge device that produces a flow of liquid within an exposure zone, and a cleaning device that cleans a portion of the projection optical system having been contacted with the immersion liquid by means of a cleaning gas. In an embodiment, the cleaning device includes an ozone generation unit produces a flow of ozone into the exposure zone. In embodiments, the apparatus includes a stage that includes a dose sensor and/or an ultra-violet light source. A method for insitu cleaning of a final lens element within an immersion lithography system having an immersion fluid showerhead that provides immersion fluid to an exposure zone of the immersion lithography system is also provided.

Abstract: A lithographic apparatus comprises an immersion fluid system and an interferometric temperature detection system. The immersion fluid system is configured to provide immersion fluid to an exposure system. The interferometric temperature detection system is configured to measure a temperature of the immersion fluid.

Abstract: A lithographic system includes a laser outputting a laser beam; a beamsplitter dividing the laser beam into a plurality of beams; and a prism for forming interference fringes on a substrate using the plurality of beams. Resolution of the lithographic system is adjustable without replacing any optical components in an optical path of the lithographic system. The beamsplitter is movable along the optical path to adjust the resolution. The prism includes a plurality of sets of facets, each set of facets corresponding to a particular resolution. Each set of facets corresponds to a particular beamsplitter position along the optical path, and/or to a particular resolution. The beamsplitter includes a linear grating or a checkerboard grating. The beams are N-way symmetric. The resolution is adjustable. A numerical aperture of the system is adjustable by moving the beamsplitter along the optical path. A liquid can be between the substrate and the prism.

Abstract: A lithographic system includes a source of a laser beam; a beamsplitter dividing the laser beam into a plurality of beams; and a plurality of reflecting surfaces that forms interference fringes on a substrate using the plurality of beams. Resolution of the lithographic system is adjustable by adjusting angular orientation of the reflecting surfaces. The beamsplitter is movable along the optical path to adjust the resolution. The reflecting surfaces may be facets of a prism. Each reflecting surface corresponds to a particular beamsplitter position along the optical path, and/or to a particular resolution. The beamsplitter includes a linear grating or a checkerboard grating. The beams are N-way symmetric. A numerical aperture of the system is adjustable by moving the beamsplitter along the optical path. A liquid can be between the substrate and the prism.

Abstract: A system and method form a nanodisk that can be used to form isolated data bits on a memory disk. The imprint stamp is formed from first and second overlapping patterns, where the patterns are selectively etched. The selective etching leaves either pits or posts on the imprint stamp. The pits or posts are imprinted on the memory disk, leaving either pits or posts on the memory disk. The pits or posts on the memory disk are processed to form relatively small and dense isolated data bits. Instability of the isolated data bits caused by outside magnetic and thermal influences is substantially eliminated.

Abstract: The present invention provides systems and methods for improved lithographic printing with polarized light. In embodiments of the present invention, polarized light (radially or tangentially polarized) is used to illuminate a phase-shift mask (PSM) and produce an exposure beam. A negative photoresist layer is then exposed by light in the exposure beam. A chromeless PSM can be used. In further embodiments of the present invention, radially polarized light is used to illuminate a mask and produce an exposure beam. A positive photoresist layer is then exposed by light in the exposure beam. The mask can be an attenuating PSM or binary mask. A very high image quality is obtained even when printing contact holes at various pitches in low k applications.

Abstract: An immersion lithography apparatus is provided that includes an energy source, a projection optical system, a stage, a showerhead including an immersion liquid supply device and an immersion liquid discharge device that produces a flow of liquid within an exposure zone, and a cleaning device that cleans a portion of the projection optical system having been contacted with the immersion liquid by means of a cleaning gas. In an embodiment, the cleaning device includes a gas supply device and a gas discharge device that produce a flow of cleaning gas into the exposure zone. In embodiments, the apparatus includes a stage that includes a dose sensor and/or an ultra-violet light source. A method for insitu cleaning of a final lens element within an immersion lithography system having an immersion fluid showerhead that provides immersion fluid to an exposure zone of the immersion lithography system is also provided.

Abstract: Lithographic Apparatus, a Dryer and a Method of Removing Liquid from a Surface A new way of drying and/or wetting a surface, such as a top surface of a substrate, is disclosed which is useful in immersion lithography. The surface is placed under a single phase extractor and a priming liquid is delivered between the single phase extractor and the surface. The single phase extractor is only activated after the priming liquid has been provided between the single phase extractor and the surface. Priming liquid is delivered to the single phase extractor during the whole of the drying and/or wetting process.

Abstract: Provided is a method and system for manufacturing a hard drive platen. The method includes depositing two or more types of film around a central core to form a plurality of film layers, each film layer being of a different type than its adjacent layers. Next, the deposited film layers are sectioned to expose a patterned surface. The patterned surface is then planarized and selectively etched to expose patterns comprised of one of the types of film to a predetermined depth to produce a selectively etched surface. Magnetic material it deposited within etches of the surface and the surface is then planarized to form separated magnetic tracks therein.

Abstract: Provided is a method and system for manufacturing a nano-plate. The method includes depositing two or more types of film around a central core to form a plurality of film layers, each film layer being of a different type than its adjacent layers. Next, the deposited film layers are sectioned to expose a patterned surface. Finally, the patterned surface is then planarized and selectively etched to form a relief pattern which can be used as an imprint stamp.

Abstract: A system and method form a nanodisk that can be used to form isolated data bits on a memory disk. The imprint stamp is formed from first and second overlapping patterns, where the patterns are selectively etched. The selective etching leaves either pits or posts on the imprint stamp. The pits or posts are imprinted on the memory disk, leaving either pits or posts on the memory disk. The pits or posts on the memory disk are processed to form relatively small and dense isolated data bits. Instability of the isolated data bits caused by outside magnetic and thermal influences is substantially eliminated.

Abstract: Provided are methods and systems for imprinting a pattern formed on surfaces of an imprint mask onto a double-sided substrate. The method includes deforming the surfaces of the first and second imprint stamps to produce respective first and second deformed surfaces, each having an arc therein. A pressure is applied to bring the deformed first and second surfaces into intimate contact with the first and second substrate surfaces, respectively. The applied pressure substantially flattens the deformed surfaces. To separate the two surfaces, the applied pressure is released. The method also includes transporting a substrate having first and second patterning surfaces and a shaped edge using a carrier having a holding portion that holds the shaped edge of the substrate, the holding surface having a shape that is complementary to the shaped edge of the substrate, such that the patterning surfaces remain untouched by the carrier.

Abstract: Immersion lithography aberration control systems and methods that compensate for a heating effect of exposure energy in an immersion fluid across an exposure zone are provided. An aberration control system includes actuators that adjust optical elements within the immersion lithography system and a fluid heating compensation module coupled to the actuators. The fluid heating adjustment module determines actuator commands to make aberration adjustments to optical elements within the immersion lithography system based on changes in one or more of a flow rate of the immersion liquid, an exposure dose and a reticle pattern image. In an embodiment, the aberration control system includes an interferometric sensor that pre-calibrates aberrations based on changes in operating characteristics related to the immersion fluid. Methods are provided that calibrate aberrations, determine actuator adjustments and implement actuator adjustments upon changes in operating characteristics to control aberration effects.

Abstract: A lithographic apparatus is presented. The lithographic apparatus includes a beam splitter configured to split a radiation beam into a plurality of radiation beams; a substrate stage configured to support a substrate; a beam combiner adapted to redirect and combine at least a portion of the plurality of radiation beams to form an interference pattern on the substrate; and a control unit in communication with the substrate stage and a radiation source configured to output the beam of radiation, the control unit configured to synchronize a motion of the substrate stage with a repetition rate at which the beam of radiation is output by the radiation source.

Abstract: A system and method are utilized to equalize intensity or energy in various diffraction orders of a patterned beam. The patterned beam is formed using a diffractive patterning device. An attenuator is placed at a pupil of a projection system to attenuate respective diffraction orders of the patterned beam. The projection device is also used to project the patterned beam onto a target portion of a substrate, after the respective attenuations.

Abstract: Lithographic Apparatus and Device Manufacturing Method A system for tuning the refractive index of immersion liquid in an immersion lithographic apparatus is disclosed. Two or more immersion liquids of different refractive index are mixed together in order to achieve a desired refractive index. Further, the fluids may be conditioned and treated to maintain optical characteristics.

Abstract: Provided are a method and system for imprinting a pattern formed on surfaces of an imprint mask onto a double-sided substrate. A method includes deforming the surfaces of the first and second imprint stamps to produce respective first and second deformed surfaces, each having an arc therein. A Pressure is applied to bring the deformed first and second surfaces into intimate contact with the first and second substrate surfaces, respectively. The applied pressure substantially flattens the deformed surfaces. And to separate the two surfaces, the applied pressure is released.

Abstract: The invention relates to a patterned grid polarizer for use in lithography, comprising a substrate that is transparent to ultraviolet (UV) light; and an array of elements patterned on the substrate, wherein the elements polarize UV light. The array of elements can be patterned to produce tangentially or radially polarized UV light.