Abstract: A lithographic apparatus including a fluid handling structure configured to contain immersion fluid in a space adjacent to an upper surface of the substrate table and/or a substrate located in a recess of the substrate table, a cover having a planar main body that, in use, extends around a substrate from the upper surface to a peripheral section of an upper major face of the substrate in order to cover a gap between an edge of the recess and an edge of the substrate, and an immersion fluid film disruptor, configured to disrupt the formation of a film of immersion fluid between an edge of the cover and immersion fluid contained by the fluid handling structure during movement of the substrate table relative to the fluid handling structure.

Abstract: In general, one aspect of the technology described can be embodied in methods that include the action of applying a writing mechanism having non-isotropic writing properties resulting from different degrees of coherence interaction in a sweep direction and a cross-sweep direction, writing an image pattern twice on a work piece using the writing mechanism rotated relative to the image pattern written on the workpiece between first and second writings, whereby writing with the rotated writing mechanism averages the non-isotropic properties. The lesser included angle separating first and second relative directions of movement between a workpiece and writing mechanism may be 20 degrees or greater, or somewhat less, under conditions described herein.

Abstract: Projection systems and methods with mechanically decoupled metrology plates according to embodiments of the present invention can be used to characterize and compensate for misalignment and aberration in production images due to thermal and mechanical effects. Sensors on the metrology plate measure the position of the metrology plate relative to the image and to the substrate during exposure of the substrate to the production image. Data from the sensors are used to adjust the projection optics and/or substrate dynamically to correct or compensate for alignment errors and aberration-induced errors. Compared to prior art systems and methods, the projection systems and methods described herein offer greater design flexibility and relaxed constraints on mechanical stability and thermally induced expansion. In addition, decoupled metrology plates can be used to align two or more objectives simultaneously and independently.

Abstract: An exposure apparatus which projects a pattern of an original onto a substrate via a liquid to expose the substrate, includes a substrate stage which holds the substrate and moves, the substrate stage including a peripheral member arranged to surround a region in which the substrate is arranged, the peripheral member having a holding surface which holds the liquid, wherein a trench which traps the liquid is formed in the peripheral member, and the trench is arranged to surround the region in which the substrate is arranged, and includes a bottom portion, an inner-side surface extending from the holding surface toward the bottom portion, and an outer-side surface, the inner-side surface having a slant which increases stepwise or continuously in a direction away from the holding surface, and the outer-side surface is provided with a spattering preventing portion which prevents spattering of the liquid trapped by the trench.

Abstract: A lithographic apparatus includes: a light-shielding plate which includes, on an edge thereof, an arc overlapping with a circular boundary line that defines a region onto which the pattern is transferred and is located inside an outer periphery of a substrate, and blocks the light to prevent the light from being incident on an outer peripheral region located outside the circular boundary line; a first driving unit which rotates the light-shielding plate about an axis parallel to an optical axis of the irradiation system; and a second driving unit which linearly drives the light-shielding plate within a plane perpendicular to the optical axis.

Abstract: An apparatus and method for cleaning a contaminated surface of a lithographic apparatus are provided. A liquid confinement structure comprises at least two openings used to supply and extract liquid to a gap below the structure. The direction of flow between the openings can be switched. Liquid may be supplied to the gap radially outward of an opening adapted for dual flow. Supply and extraction lines to respectively supply liquid to and extract liquid from the liquid confinement structure have an inner surface that is resistant to corrosion by an organic liquid. A corrosive cleaning fluid can be used to clean photo resist contamination.

Abstract: According to an example embodiment, a method to determine an exposure start position and orientation includes loading a substrate on a moving table. The substrate includes at least one alignment mark of a first set of alignment marks of a first pattern layer patterned thereon. At least one alignment mark of a second set of alignment marks of a second pattern layer is exposed on the substrate using maskless lithography. A position of the at least one alignment mark of the first set of alignment marks and a position of the at least one alignment mark of the second set of alignment marks on the substrate is measured. A relative orientation difference between a desired exposure start orientation and an obtained exposure start orientation is acquired using the measured positions of the at least one alignment mark of the first set of alignment marks and the at least one alignment mark of the second set of alignment marks.

Abstract: A stage apparatus includes: a moving stage, which moves along a movement plane; a first moving table, which holds a specimen while being able to move with respect to the moving stage; and a second moving table, which is provided on the moving stage and, when the first moving table has moved from a first position to a second position, is positioned at the first position.

Abstract: An apparatus, a method of designing the apparatus, a tool using the apparatus and a method of using the apparatus for optimizing optical photolithography during formation of integrated circuits. The apparatus includes: an asymmetrical complementary dipole element including: first and second openings being equidistant and mirror images about a first axis, the first and second openings having essentially a same first area and a same first optical density relative to a selected wavelength of light; third and fourth openings being equidistant and mirror images about a second axis, the third and fourth openings having essentially a same second area, and a same second optical density relative to the selected wavelength of light; and wherein the first axis is perpendicular to the second axis and the first and second optical densities are different.

Abstract: A lithographic projection apparatus includes a projection optical assembly having a final optical element, a stage assembly including a substrate table on which a substrate is supported, the substrate supported by the substrate table being exposed with an exposure beam from the final optical element of the projection optical assembly through an immersion liquid, a confinement member which encircles a portion of a path of the exposure beam, and a movable member which is movable in a space between the confinement member and the substrate, the substrate table, or both, the space being divided by the movable member into a first portion between the confinement member and the movable member and a second portion between the movable member and the substrate, the substrate table, or both. The movable member has a recovery outlet from which the immersion liquid in the second portion is removed.

Abstract: An apparatus, a method of designing the apparatus, a tool using the apparatus and a method of using the apparatus for optimizing optical photolithography during formation of integrated circuits. The apparatus includes: an asymmetrical complementary dipole element including: first and second openings being equidistant and minor images about a first axis, the first and second openings having essentially a same first area and a same first optical density relative to a selected wavelength of light; third and fourth openings being equidistant and minor images about a second axis, the third and fourth openings having essentially a same second area, and a same second optical density relative to the selected wavelength of light; and wherein the first axis is perpendicular to the second axis and the first and second optical densities are different.

Abstract: A lithographic apparatus includes a radiation system for providing a beam of radiation from radiation emitted by a radiation source. The radiation system includes a contaminant trap for trapping material emanating from the radiation source. The rotation contaminant trap includes a multiple number of elements extending in a radial direction from a common rotation trap axis and being arranged for allowing contaminant material emanating from the radiation source to deposit during propagation of the radiation beam in the radiation system. The radiation system further includes a contaminant catch for receiving contaminant material particles from the rotation trap elements, the contaminant catch having a constitution, during operation of the radiation, for retaining said contaminant material particles.

Abstract: A position sensor is configured to measure a position data of a target. The position sensor includes a radiation source configured to irradiate a radiation beam, a first grating configured to diffract the radiation beam in a first diffraction direction into at least a first order diffraction beam, and a second grating, arranged in an optical path of the first order diffraction beam, the second grating being configured to diffract the first order diffraction beam diffracted at the first grating in a second diffraction direction substantially perpendicular to the first diffraction direction. The second grating is connected to the target. A first detector is configured to detect at least a part of the beam diffracted by the first grating, and at least one second detector is configured to detect at least part of the beam diffracted by the first grating and the second grating.

Abstract: An object of the present invention is a photomask drying device which includes: a sealed chamber containing at least one photomask, a pumping unit to set up and maintain vacuum within said chamber, a support for the photomask placed within said chamber, infrared radiation means placed within said chamber, a system for injecting gas into said chamber characterized in that the infrared radiation means comprise a plurality of infrared radiation sources distributed in a plane parallel to the plane of the photomask in such a way that the distance from the photomask to the infrared radiation means is given by the relationship: D=1.

Abstract: An exposure apparatus includes an immersion space forming member (70) which fills an optical path space (K1) for exposure light (EL) with a first liquid (LQ) to form an immersion space, and a temperature regulating mechanism (60) which suppresses a change in the temperature of the immersion space forming member (70) accompanying deactivation of formation of the immersion space.

Abstract: In the present invention, a number of times the brightness changes detected at the same position while a substrate conveys are added up in the conveying direction, thereby obtaining a plurality of edge count data, and then, a plurality of positions of long sides of patterns parallel to the conveying direction is identified based on the plurality of edge count data exceeding a predetermined threshold value, middle point positions of a plurality of proximity pairs are calculated, and a middle point position close to the target position preset in the imaging device is selected from the plurality of middle point positions of the proximity pairs, an amount of position displacement between the selected middle point position and the target position of imaging device is calculated, and the photomask in the direction substantially perpendicular to the conveying direction so that the amount of position displacement is a predetermined value.

Abstract: A method for the production of a mirror element (10) that has a reflective coating (10a) for the EUV wavelength range and a substrate (10b). The substrate (10b) is pre-compacted by hot isostatic pressing, and the reflective coating (10a) is applied to the pre-compacted substrate (10b). In the method, either the pre-compacting of the substrate (10b) is performed until a saturation value of the compaction of the substrate (10b) by long-term EUV irradiation is reached, or, for further compaction, the pre-compacted substrate (10b) is irradiated, preferably homogeneously, with ions (16) and/or with electrons in a surface region (15) in which the coating (10a) has been or will be applied. A mirror element (10) for the EUV wavelength range associated with the method has a substrate (10b) pre-compacted by hot isostatic pressing. Such a mirror element (10) is suitable to be provided in an EUV projection exposure system.

Abstract: A fluid handling structure to confine immersion liquid in a space between a projection system and a facing surface of a substrate, of a table to support the substrate, or both, is disclosed. The fluid handling structure includes a transponder to dissolve at least some of the gas in a bubble in the immersion liquid or to control a bubble in the immersion liquid so that it avoids entering an optical path of a beam from the projection system.

Abstract: For angular resolved spectrometry a radiation beam is used having an illumination profile having four quadrants is used. The first and third quadrants are illuminated whereas the second and fourth quadrants aren't illuminated. The resulting pupil plane is thus also divided into four quadrants with only the zeroth order diffraction pattern appearing in the first and third quadrants and only the first order diffraction pattern appearing in the second and third quadrants.

Abstract: In EUV lithography apparatuses (10), it is proposed, in order to lengthen the lifetime of contamination-sensitive components, to arrange them in a protection module. The protection module comprises a housing (23-29) having at least one opening (37-47), in which at least one component (13a, 13b, 15, 16, 18, 19) is arranged and at which one or more gas feeds (30-36) are provided in order to introduce a gas flow into the housing (23-29), which emerges through the at least one opening (37-47). In order to effectively prevent contaminating substances from penetrating into the protection module, a light source (48-56) is arranged at the at least one opening (37-47), which light source illuminates the opening (37-47) with one or more wavelengths by which the contaminating substances can be dissociated before they penetrate through the opening (37-47).