Abstract: A wavefront measurement system has a source of electromagnetic radiation. An imaging system focuses the electromagnetic radiation at an object plane. A first grating is positioned in the object plane and has a plurality of rulings with randomized height. A stage moves the first grating parallel to the rulings. A projection optical system projects an image of the first grating onto an image plane. A second grating is at the image plane. A detector behind the second grating receives a fringe pattern produced by the second grating.

Abstract: A method and system are provided for forming a pattern within an area of a photosensitive surface. An exemplary method includes performing a first exposure of the photosensitive surface in accordance with predetermined image data, wherein the first exposure occurs during a first pass and produces a first image within the area. The image data is adjusted to compensate for identified image deficiencies image deficiencies, the image deficiencies being within a region of the first image. A second exposure, of the photosensitive surface, is performed in accordance with the adjusted image data during a second pass.

Abstract: A liquid immersion photolithography system includes an exposure system that exposes a substrate with electromagnetic radiation and includes a projection optical system that focuses the electromagnetic radiation on the substrate. A liquid supply system provides liquid flow between the projection optical system and the substrate. An optional plurality of micronozzles are arranged around the periphery of one side of the projection optical system so as to provide a substantially uniform velocity distribution of the liquid flow in an area where the substrate is being exposed.

Abstract: A liquid immersion photolithography system includes an exposure system that exposes a substrate with electromagnetic radiation and includes a projection optical system that focuses the electromagnetic radiation on the substrate. A liquid supply system provides liquid flow between the projection optical system and the substrate. An optional plurality of micronozzles are arranged around the periphery of one side of the projection optical system so as to provide a substantially uniform velocity distribution of the liquid flow in an area where the substrate is being exposed.

Abstract: An exposure system for manufacturing flat panel displays (FPDs) includes a reticle stage and a substrate stage. A magnification reflective optical system images the reticle onto the substrate. The system may be a 2× magnification system, or another magnification that is compatible with currently available mask sizes. By writing reticles with circuit pattern dimensions that are one-half the desired size for an FPD, a 2× optical system can be used to expose FPDs. The designs for the 1.5× and larger magnification optical systems all typically have at least three powered mirrors. A corrector, positioned either near the reticle or near the substrate, can be added to the three mirror design to improve the systems optical performance. The corrector may be a reflective, or a refractive design. The corrector can have an aspheric surface, and optionally a powered surface.

Abstract: The present invention provides an ultra-thin high-precision glass optic and method of manufacturing the same. The optic has an axial thickness that is less than 1,000 microns. A pattern and/or coating is disposed on a surface of the optic to provide attenuation of light in an optical system. In an embodiment, the optic is manufactured by disposing a pattern on a surface of a reticle. The pattern is covered with a first protective coating to protect the pattern. Individual optics are cut from the reticle so that each optic includes a portion of the pattern. The optic is thinned by removing material until it has an axial thickness of less than 1,000 microns. The optic is cleaned after thinning and covered with an anti-reflective coating.

Abstract: A wafer chuck for use in a lithographic apparatus, which includes a low-thermal expansion glass ceramic substrate, a silicon silicon carbide layer, and a bonding layer comprising silicate having a strength of at least about 5 megapascals, the bonding layer attaching the silicon silicon carbide layer to the substrate is described. Also, a method of forming a wafer chuck for use in a lithographic apparatus, which includes coating a portion of one or both of a low-thermal expansion glass ceramic substrate and a silicon silicon carbide layer with a bonding solution, and contacting the substrate and the silicon silicon carbide layer to bond the substrate and the silicon silicon carbide layer together is described.

Abstract: A maskless lithography system that writes patterns on an object. The system can include an illumination system, the object, spatial light modulators (SLMs), and a controller. The SLMs can pattern light from the illumination system before the object receives the light. The SLMs can include a leading set and a trailing set of the SLMs. The SLMs in the leading and trailing sets change based on a scanning direction of the object. The controller can transmit control signals to the SLMs based on at least one of light pulse period information, physical layout information about the SLMs, and scanning speed of the object. The system can also correct for dose non-uniformity using various methods.

Abstract: This invention relates to an apparatus for optical beam shaping and diffusing, a method for making the apparatus, and a method for using the apparatus. The apparatus comprises a crystalline material object shaped to fit within an optical train and with a pattern of surface texture along an optical path. Surface removal processes are applied to a portion of a surface of an object made of a crystalline material to form a surface texture pattern at that portion of the surface of the object. The surface texture pattern depends upon: (1) the identity of the crystalline material and (2) the orientation of crystal lattice axes within the object with respect to the portion of the surface of the object where the pattern of surface texture is to be formed. Processes for making the apparatus include, but are not limited to, mechanical grinding, ablating, chemical etching, plasma etching, ion milling, and combinations thereof.

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: A light patterning system comprises an illumination system that supplies a beam of radiation having a certain wavelength (?). An array of reflective pixels patterns the beam, wherein the array includes pixels having at least a first tilting mirror that is logically coupled to a second tilting mirror. In an embodiment, the first and second tilting mirrors are (i) substantially adjacent to each other; and (ii) offset in height from each other by a first mirror displacement. A projection system is included that projects the patterned beam onto a target. In alternate embodiment, the array of reflective pixels includes pixels having first through fourth tilting mirrors that are logically coupled to each other. The first through fourth tilting mirrors are (i) respectively offset in height from a reference plane by first through fourth mirror displacements, and (ii) are respectively arranged clockwise in a substantially square pattern.

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: A method of calculating an aerial image of a spatial light modulator array includes calculating pair-wise interference between pixels of the spatial light modulator array; calculating effective graytones corresponding to modulation states of the pixels; and calculating the aerial image based on the pair-wise interference and the effective graytones. The graytones depend only on the modulation states of the pixels. The pair-wise interference depends only on position variables. The position variables are position in an image plane and position in a plane of a source of electromagnetic radiation. The pair-wise interference can be represented by a matrix of functions. The pair-wise interference can be represented by a four dimensional matrix. The effective graytones are approximated using sinc functions, or using polynomial functions.

Abstract: A system if used to compensate for guide flatness errors and/or shifting of a support. The system comprises one or more of the supports, an actuating system, the guide, a fluid or magnetic bearing, and a compensation system. The one or more support devices have one or more openings. The support devices are coupled to the actuating system, which is configured to move the support devices. The guide passes through respective ones of the openings. The fluid or magnetic bearings are configured to guide the respective support devices along the guides. The compensation system is coupled to respective ones of the support devices adjacent each of the fluid or magnetic bearings. The compensation system is configured to compensate for any non-straight areas of the guides or shifting (e.g., thermal shifting) of the support devices, which is done through moving of the support devices with respect to the guides during movement of the support devices along the guides.

Abstract: The present invention provides systems and methods of controlling local environment. In one embodiment, incoming air enters a contactor such the Direct Contact Cooler-Condenser (DCCC) where the air contacts water distributed on the contact media. After passing through the DCCC, the air is saturated at a temperature equal or close to that of the water. Depending on the state of the incoming air, in the DCCC will be humidified or dehumidified to yield saturated air at the desired humidity ratio. In one embodiment, a blower draws air through the DCCC and blows into the heater. The heater heats the air to the desired dry-bulb temperature. Before exiting, the air may pass through a filter.

Abstract: An iterative method of producing optimized setpoint data for controlling the actuation of elements of an array of individually controllable elements in a maskless system and systems therefore. The optimization is based on estimation of a device structure that can utilizes one or more of the following factors: the low-pass characteristics of the projection system, the configuration of the illumination system, and the process window properties.

Abstract: A trajectory planning process receives data generated by high-level control software. This data defines positions and scan velocities. The trajectory planning process creates sequences of constant acceleration intervals that allow critical motions to be executed at maximum throughput. The trajectory planning process outputs a profile. A profile executor, using the profile output by the trajectory planner process, generates continuous synchronized, filtered, multi-axis position and acceleration commands that drive control servos. Time intervals generated by the trajectory planner are quantized to be integer multiples of a real time clock period. The trajectory planner outputs have infinite jerk, but are smoothed by filters in the profile executor to both limit jerk and minimize servo-tracking errors. The trajectory planner allows time for the profile executor filters, but does not restrict fine tuning of the shape of these filters, provided that the width of the tuned filter does not exceed the allowed time.

Abstract: Provided are a method and system for projecting an illumination beam to an image plane. The method includes producing a sample of the illumination beam and projecting the sample to a secondary image plane. Next, an illumination uniformity profile associated with the projected sample is measured while the received illumination beam is being projected to the image plane.

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 system and method are used to direct a radiation beam to illuminate non-perpendicularly a patterning array of individually controllable elements used for patterning the radiation beam. The individually controllable elements can change a telecentricity of the radiation beam. Projection of the radiation beam onto the individually controllable elements can be by a concave mirror or use a folding mirror placed in an object field of the individually controllable elements. Alternatively, the individually controllable elements can change the optical axis of the radiation beam.