Abstract: A patterning device support (1100) for controlling a temperature of a patterning device (1102) can include a movable component (1104). The movable component can include a gas inlet (1108) for supplying a gas flow across a surface of the patterning device and a gas outlet (1110) for extracting the gas flow. The patterning device support can also include a gas flow generator (1118) coupled to a duct (1114, 1116) for recirculating the gas flow from the gas outlet to the gas inlet.

Abstract: A system for controlling temperature of a patterning device in a lithographic apparatus is discussed. The system includes a patterning device support configured to support a patterning device and a reticle cooling system configured to provide substantially uniform temperature distribution across the patterning device. The reticle cooling system includes a first and second array of gas inlets configured to provide a first and second gas flow along a first and second direction across a surface of the patterning device, respectively, where first and second directions are opposite to each other. The reticle cooling system further includes a switching control system configured to control operation of the first and second arrays of gas inlets.

Abstract: A system and method are provided for determining deformation of a patterning device and/or shift position of the patterning device relative. The system includes a first sensing sub-system that measures respective positions of a plurality of reference marks on the patterning device, and a second sensing sub-system that measures positions of the edge of the patterning device relative to the support. The system further includes a controller to determine an absolute position of the patterned portion and change in the absolute position based on measured respective positions of marks on the patterning device, determine a change in a relative position of the edge of the patterned device based on the measured edge positions, and estimate a change in a position of the patterning device relative to the support and a change in a pattern distortion of the patterned portion of the patterning device over a time period.

Abstract: A lithographic apparatus having an optical column capable of creating a pattern on a target portion of a substrate is disclosed. The optical column may have a self-emissive contrast device configured to emit a beam, and a projection system configured to project the beam onto the target portion. The apparatus may also have an actuator to move the optical column or a part thereof with respect to the substrate. The apparatus may be constructed to reduce the optical effect of density variation in a medium around the moving part of the optical column on the beam.

Abstract: In an embodiment, a lithographic apparatus is disclosed that includes a modulator configured to expose an exposure area of the substrate to a plurality of beams modulated according to a desired pattern and a projection system configured to project the modulated beams onto the substrate. The modulator may be moveable with respect the exposure area and/or the projection system may have an array of lenses to receive the plurality of beams, the array of lenses moveable with respect to the exposure area.

Abstract: A system to control the focus of a mask-less lithographic apparatus, the apparatus including a projection system to project an image of a programmable patterning device onto a substrate. A first actuator system is configured to move at least one of the lenses of the projection system in a direction perpendicular to the optical axis of the projection system. A radiation beam expander is configured to project an image of the programmable patterning device onto the at least one lens. A second actuator system is configured to move the radiation beam expander in a direction parallel to the optical axis of the projection system in order to control the focus of the image projected onto the substrate.

Abstract: A lithographic apparatus having an optical column capable of projecting a beam on a target portion on a substrate held by the substrate support. The optical column may have a self-emissive contrast device to emit the beam. The optical column may include a projection system to project the beam onto the target portion. The target portion has a height in a scanning direction of the substrate and a tangential width mainly perpendicular to the scanning direction, wherein a scanning speed of the substrate in the scanning direction divided by the height substantially corresponds with a rotating speed of the optical column or a part thereof divided by the tangential width of the target portion.

Abstract: A lithographic apparatus having an optical column capable of creating a pattern on a target portion of a substrate is disclosed. The optical column may have a self-emissive contrast device configured to emit a beam, and a projection system configured to project the beam onto the target portion. The apparatus may also have an actuator to move the optical column or a part thereof with respect to the substrate. The apparatus may be constructed to reduce the optical effect of density variation in a medium around the moving part of the optical column on the beam.

Abstract: A system is disclosed for reducing overlay errors by controlling gas flow around a patterning device of a lithographic apparatus. The lithographic apparatus includes an illumination system configured to condition a radiation beam. The lithographic apparatus further includes a movable stage comprising a support structure that may be configured to support a patterning device. The patterning device may be configured to impart the radiation beam with a pattern in its cross-section to form a patterned radiation beam. In addition, the lithographic apparatus comprises a plate (410) positioned between the movable stage (401) and the projection system (208). The plate includes an opening (411) that comprises a first sidewall (411a) and a second sidewall (411b). The plate may be configured to provide a gas flow pattern (424) in a region between the movable stage and the projection system that is substantially perpendicular to an optical axis of the illumination system.

Abstract: A patterning device support (1100) for controlling a temperature of a patterning device (1102) can include a movable component (1104). The movable component can include a gas inlet (1108) for supplying a gas flow across a surface of the patterning device and a gas outlet (1110) for extracting the gas flow. The patterning device support can also include a gas flow generator (1118) coupled to a duct (1114, 1116) for recirculating the gas flow from the gas outlet to the gas inlet.

Abstract: A lithographic apparatus having an optical column capable of creating a pattern on a target portion of a substrate is disclosed. The optical column may have a self-emissive contrast device configured to emit a beam, and a projection system configured to project the beam onto the target portion. The apparatus may also have an actuator to move the optical column or a part thereof with respect to the substrate. The apparatus may be constructed to reduce the optical effect of density variation in a medium around the moving part of the optical column on the beam.

Abstract: A system for controlling temperature of a patterning device in a lithographic apparatus is discussed. The system includes a patterning device support configured to support a patterning device and a reticle cooling system configured to provide substantially uniform temperature distribution across the patterning device. The reticle cooling system includes a first and second array of gas inlets configured to provide a first and second gas flow along a first and second direction across a surface of the patterning device, respectively, where first and second directions are opposite to each other. The reticle cooling system further includes a switching control system configured to control operation of the first and second arrays of gas inlets.

Abstract: Methods and systems are described for cleaning contamination from the surface of an object within a lithographic apparatus. A lithographic apparatus is provided that includes an illumination system configured to condition a radiation beam, a support constructed to hold a patterning device (302), the patterning device being capable of imparting the radiation beam with a pattern in its cross-section to form a patterned radiation beam, a substrate table constructed to hold a substrate, and a projection system configured to project the patterned radiation beam onto a target portion of the substrate. The lithographic apparatus further includes a cleaning system (500) for cleaning particles off of a surface of either the support or the patterning device. The cleaning system includes a cleaning surface (502) designed to contact the surface of either the support or the patterning device.

Abstract: Systems and methods are disclosed for controlling the heating of a reticle. In one embodiment, a plurality of radiation sources generates a plurality of radiation beams (206) and delivers them to a patterning device (210) that absorbs a portion of the radiation from the beams and develops a spatially dependent heating profile. In a further embodiment, a plurality of resistive heating sources (906) generates heat in response to an applied voltage or current. The generated heat is absorbed by the patterning device from the resistive heating sources and leads to the development of a spatially dependent heating profile. Thermal stresses, strains, and deformations can be controlled by controlling the spatially dependent heating profile.

Abstract: A system for controlling temperature of a patterning device in a lithographic apparatus is discussed. The system includes a cooling system and a heating system. The cooling system is configured to direct a gas flow along a first direction across a surface of the patterning device to remove heat from the patterning device prior to exposing the patterning device or during exposure of the patterning device. The heating system is configured to selectively heat areas on the surface of the patterning device prior to exposing the patterning device or during exposure of the patterning device. The selective heating and the heat removal achieve a substantially uniform temperature distribution in the patterning.

Abstract: A lithographic apparatus having an optical column capable of creating a pattern on a target portion of the substrate. The optical column may be provided with a self-emissive contrast device configured to emit a beam and a projection system configured to project the beam onto the target portion. The apparatus may be provided with an actuator to move the optical column or a part thereof with respect to the substrate. An optical sensor device is provided which is movable in respect of the optical columns and has a range of movement which enables the optical sensor device to move through a projection area of each of the optical columns to measure a beam of each of the optical columns.

Abstract: In a lithographic apparatus, a slip of a patterning device relative to a support, the support constructed to support the patterning device, may be provided by measuring a position of the support relative to a first structure of the lithographic apparatus; measuring a position of the patterning device relative to a second structure of the lithographic apparatus; determining a correlation between the position of the patterning device and the position of the support from the measured position of the support, the measured position of the patterning device, and the mutual positions of the first and second structures; and deriving from the correlation a slip of the patterning device relative to the support. The structure may include a projection system to project a radiation beam patterned by the patterning device. The projection system may be connected to a frame, such as a metrology frame of the lithographic apparatus.

Abstract: In an embodiment, a lithographic apparatus is disclosed that includes a modulator configured to expose an exposure area of the substrate to a plurality of beams modulated according to a desired pattern and a projection system configured to project the modulated beams onto the substrate. The modulator includes a deflector to displace the plurality of beams with respect to an exposure area.

Abstract: In an embodiment, a lithographic apparatus is disclosed that includes a modulator configured to expose an exposure area of the substrate to a plurality of beams modulated according to a desired pattern and a projection system configured to project the modulated beams onto the substrate. The modulator may be moveable with respect the exposure area and/or the projection system may have an array of lenses to receive the plurality of beams, the array of lenses moveable with respect to the exposure area.

Abstract: Systems and methods for processing wafers, a combined post expose bake and chill unit, and an interface are disclosed. An exemplary system includes a lithography tool, local track, transfer device, transfer device handler, interface unit, and controller to schedule processing. An exemplary combined post expose bake and chill unit includes an enclosure having an opening in its side, and a bake unit and a chill unit in the enclosure. An exemplary interface includes a plurality of enclosures arranged around robot(s) that transfer wafers among the enclosures, one of the plurality of enclosures being an integrated bake and chill unit.