Abstract: An apparatus to measure the position of a mark, the apparatus including an illumination arrangement to direct radiation across a pupil of the apparatus, the illumination arrangement including an illumination source to provide multiple-wavelength radiation of substantially equal polarization and a wave plate to alter the polarization of the radiation in dependency of the wavelength, such that radiation of different polarization is supplied; an objective to direct radiation on the mark using the radiation supplied by the illumination arrangement while scanning the radiation across the mark in a scanning direction; a radiation processing element to process radiation that is diffracted by the mark and received by the objective; and a detection arrangement to detect variation in an intensity of radiation output by the radiation processing element during the scanning and to calculate from the detected variation a position of the mark in at least a first direction of measurement.

Abstract: An apparatus to measure the position of a mark, the apparatus including an objective lens to direct radiation on a mark using radiation supplied by an illumination arrangement; an optical arrangement to receive radiation diffracted and specularly reflected by the mark, wherein the optical arrangement is configured to provide a first image and a second image, the first image being formed by coherently adding specularly reflected radiation and positive diffraction order radiation and the second image being formed by coherently adding specularly reflected radiation and negative diffraction order radiation; and a detection arrangement to detect variation in an intensity of radiation of the first and second images and to calculate a position of the mark in a direction of measurement therefrom.

Abstract: A system and method that bends a reticle and senses a curvature of a bent reticle in real-time. The system includes movable reticle stage, reticle vacuum clamps, sensor systems, and reticle bender. The reticle bender comprises piezo actuators. The sensor systems comprises measurement targets and corresponding sensors. The sensors are attached to the movable reticle stage and the measurement targets are attached to the reticle clamps, the reticle bender, or on reticle surfaces. The system is configured to determine a width of the reticle or distance between measurement targets at opposing ends of the reticle, measure a first rotational angle at a first end of the reticle, and measure a second local rotational angle at a second end of the reticle that is opposite to the first end. Based on the width or distance and the first and second angles, a field curvature of the reticle is determined.

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 lithographic apparatus including a uniformity correction system is disclosed. The lithographic apparatus comprises an illumination system configured to condition a beam of radiation. The illumination system comprises a uniformity correction system located at a plane configured to receive a substantially constant pupil when illuminated with the beam of radiation. The uniformity correction system includes fingers configured to be movable into and out of intersection with a radiation beam so as to correct an intensity of respective portions of the radiation beam. A linear motor actuator arrangement drives the fingers to their respective appropriate positions to compensate for non-uniform illumination. Control is provided by a control system that precisely manipulates carriers of the fingers.

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 beam pointing and positioning system includes a first lens, movable in a first plane perpendicular to a nominal optical axis, which receives and positions a light beam. The system also includes a second lens, movable in a second plane perpendicular to the nominal optical axis, which receives and points the positioned light beam. The system is thereby capable of directing the light beam to a desired location at a desired angle. The system may also include a beam splitter that receives, transmits, and reflects the pointed light beam, one or more sensors that receive the reflected light beam, and a controller coupled to the sensor(s) and first and second lenses. The controller may control the positioning of the first and second lenses based on beam position and pointing data and/or signals received from the sensor(s). A method of positioning and pointing a light beam is also presented.

Abstract: A lithographic apparatus has a support structure configured to support a patterning device, the patterning device serving to pattern a radiation beam according to a desired pattern and having a planar main surface through which the radiation beam passes; an outlet opening configured to direct a flow of a gas onto the patterning device; and an inlet opening configured to extract the gas which has exited the outlet opening, wherein the outlet opening and inlet opening are in a facing surface facing the planar main surface of the patterning device.

Abstract: Disclosed are systems and methods for a fluid transportation system having a first flexible tube with an inner wall. The fluid transportation system also has a second flexible tube with an outer wall. The second tube is located inside the first tube and a standoff is located between the inner wall of the first tube and the outer wall of the second tube. The first flexible tube is configured to transport a first fluid and the second flexible tube is configured to transport a second fluid. The first and second flexible tubes are configured such that the first fluid isolates the second fluid from an ambient environment, and the first fluid can be monitored for leakage.

Abstract: Disclosed are apparatuses, methods, and lithographic systems for EUV mask inspection. An EUV mask inspection system can include an EUV illumination source, an optical system, and an image sensor. The EUV illumination source can be a standalone illumination system or integrated into the lithographic system, where the EUV illumination source can be configured to illuminate an EUV radiation beam onto a target portion of a mask. The optical system can be configured to receive at least a portion of a reflected EUV radiation beam from the target portion of the mask. Further, the image sensor can be configured to detect an aerial image corresponding to the portion of the reflected EUV radiation beam. The EUV mask inspection system can also include a data analysis device configured to analyze the aerial image for mask defects.

Abstract: Provided is a method to load a patterning device (1010) onto a reticle stage (RS) of a lithography system, a Rapid Exchange Device (RED) configured to load a patterning device (1010) onto a reticle stage (RS) of a lithography system, and a system for manufacturing a semiconductor device lithographically. The method involves sharing compliance among six degree of freedom between the reticle stage (RS) and the RED. The RED complies in only a first three degrees of freedom and the reticle stage (RS) in only a second three degrees of freedom until the reticle stage (RS) and patterning device (1010) are substantially in contact and coplanar.

Abstract: In order to effectively transfer heat from inner layers of an actuator coil to an area external to the coil, heat transfer elements, located proximate to the actuator coil, can be used. In an embodiment, a heat transfer apparatus for the actuator coil can include one or more heat transfer elements located proximate to one or more layers or one or more windings of the actuator coil and a cooling surface located proximate to the one or more heat transfer elements and to the actuator coil. In this configuration, the heat transfer apparatus can transfer heat from inner layers of the actuator coil to the cooling surface, which in turn transfers the heat to an area external to the actuator coil.

Abstract: A system and method of manufacturing a semiconductor device lithographically and an article of manufacture involving a lithographic double patterning process having a dye added to either the first or second lithographic pattern are provided. The dye is used to detect the location of the first lithographic pattern and to directly align the second lithographic pattern to it. The dye may be fluorescent, luminescent, absorbent, or reflective at a specified wavelength or a given wavelength band. The wavelength may correspond to the wavelength of an alignment beam. The dye allows for detection of the first lithographic pattern even when it is over coated with a radiation sensitive-layer (e.g., resist).

Abstract: A system and method is described for correcting aberrations caused by field curvature with a catadioptric objective. In one example, a catadioptric optical system includes a first catadioptric element and a second catadioptric element. The first catadioptric element includes a first surface positioned to reflect a beam and a second surface positioned to focus the beam reflected by the first surface. The second catadioptric element is configured to receive the beam reflected by the second surface of the first catadioptric element. The second catadioptric element includes a third surface positioned to reflect the beam, and a fourth reflective surface positioned to focus the beam reflected by the third reflective surface. A curvature of the third or fourth surfaces of the second catadioptric element is chosen to apply a positive contribution to a field curvature associated with the first catadioptric element.

Abstract: Improved low k1 lithographic imaging is disclosed by optimizing or improving an illumination polarization condition. The polarization condition may be a pre-defined spatially varying polarization, or a spatially customized local polarization of bright illumination points based on tracking a value of a desired lithographic response. Several non-traditional polarization conditions, e.g., TM/TE polarization (with or without a central TM region), diagonal polarization, and Y+X polarization (typically for dark field illumination) are disclosed, that offer substantial imaging advantages for specific lithographic problems, especially at low k1 values. The initial polarization definition may be limited to specific fixed polarization angles.

Abstract: A lithographic apparatus is described that comprises a support structure to hold an object. The object may be a patterning device or a substrate to be exposed. The support structure comprises a chuck, on which the object is supported, and an array of shear-compliant elongated elements normal to the chuck and the stage, such that first ends of the elongated elements contact a surface of the chuck and second ends of the elongated elements contact a stage. Through using the array of elongated elements, a transfer of stress between the stage and the chuck is substantially uniform, resulting in minimization of slippage of the object relative to the surface of the chuck during a deformation of the chuck due to the stress.

Abstract: An apparatus for supporting an optical element is provided. The apparatus includes a lens cell (1003) and a plurality of fingers (1000) coupled to the lens cell. Each finger includes a base (1012) configured to be coupled to the optical element when mounted therein, first (1006a) and second (1006b) flexures coupled at first respective ends to and extending from the base (1012) at a divergence angle between about 75 and 165 degrees, and a mounting member (1008) configured to couple together second respective ends of the first and second flexures. The mounting member thereby couples the base (1012) to the lens cell (1003).

Abstract: An interferometric lithography system produces a pattern having a sharp field edge and minimal optical path length difference. Light passes through a beamsplitter into an input prism. The two beams produced by the beamsplitter are reflected off respective surfaces of the input prism toward a substrate prism. The substrate prism is symmetric to the input prism such that the incidence angle at an image plane is approximately equal to the beamsplitter diffraction angle. Alternatively, light passes through a beamsplitter into a prism. The two beams produced by the beamsplitter are reflected off respective surfaces of the prism toward an output surface of the prism, such that the incidence angle at the output surface is approximately equal to the beamsplitter diffraction angle. A plurality of these interferometers can be stacked, each being optimized for a given pitch, such that the stack provides a variable pitch interferometry system.

Abstract: An electrostatic clamp configured to electrostatically clamp an article to an article support in a lithographic apparatus. The clamp comprises a first layer of material, an electrode disposed over the first layer, an isolating, dielectric or semi-dielectric material deposited between portions of the electrode, and a second layer disposed over the electrode. Further, a method of manufacturing of the electrostatic clamp is described.

Abstract: A deformable optical device includes a reflection device having a first reflecting surface and a second surface, an actuator (e.g., an integrated circuit piezoelectric actuator) having a support device and moveable extensions extending therefrom, which are coupled to the second surface, and electrodes coupled to corresponding ones of the extensions. Wavefront aberrations are detected and used to generate a control signal. The extensions are moved based on the control signal. The movement deforms the reflecting surface to correct the aberrations in the wavefront.