摘要:
Optical element having an optical surface, which optical surface is adapted to a non-spherical target shape, such that a long wave variation of the actual shape of the optical surface with respect to the target shape is limited to a maximum value of 0.2 nm, wherein the long wave variation includes only oscillations having a spatial wavelength equal to or larger than a minimum spatial wavelength of 10 mm.
摘要:
A method of positioning optical elements relative to each other uses an interferometer apparatus comprising a plurality of holograms generating beams of adjustment measuring light which are incident on optical surfaces of the optical elements. Interference patterns generated by superimposing adjustment measuring light of the beams reflected from the surfaces are indicative of positioning errors of the optical elements. The beams of adjustment measuring light may comprise focused beams forming a point focus on the optical surface and beams of light which is orthogonally incident on extended portions on the optical surface.
摘要:
A method of manufacturing an optical element having an optical surface of a target shape includes performing an interferometric test using an interferometer optics, wherein the interferometer optics includes a hologram that deflects a beam of measuring light by a substantial angle or that displaces an axis of symmetry of measuring light emerging from the hologram with respect to an axis of symmetry of measuring light incident on the hologram.
摘要:
A method of manufacturing an optical element (5) comprises testing an optical surface (3) of the optical element, using an interferometer 1a directing measuring light (23a) onto the optical surface wherein the measuring light traverses two successive holograms (44, 48) disposed in the beam path of the measuring light upstream of the optical surface.
摘要:
A projection objective for microlithography includes at least one optical assembly with optical elements which are disposed between an object plane and an image plane. The optical assembly includes at least one optical terminal element, which is disposed close to the image plane. A first immersion liquid is disposed on the image oriented surface of the optical terminal element. A second immersion liquid is disposed on the object oriented surface of the optical terminal element. The object oriented surface includes a first surface section for the imaging light to enter into the terminal element, and the image oriented surface includes a second surface portion for the imaging light to exit from the terminal element.
摘要:
The disclosure relates to a microlithographic projection exposure apparatus and a microlithographic projection exposure apparatus, as well as related components, methods and articles made by the methods. The microlithographic projection exposure apparatus includes an illumination system and a projection objective. The illumination system can illuminate a mask arranged in an object plane of the projection objective. The mask can have structures which are to be imaged. The method can include illuminating a pupil plane of the illumination system with light. The method can also include modifying, in a plane of the projection objective, the phase, amplitude and/or polarization of the light passing through that plane. The modification can be effected for at least two diffraction orders in mutually different ways. A mask-induced loss in image contrast obtained in the imaging of the structures can be reduced compared to a method without the modification.
摘要:
A projection exposure tool for microlithography for imaging mask structures of an image-providing substrate onto a substrate to be structured includes a measuring apparatus configured to determine a relative position of measurement structures disposed on a surface of one of the substrates in relation to one another in at least one lateral direction with respect to the substrate surface and to thereby simultaneously measure a number of measurement structures disposed laterally offset in relation to one another.
摘要:
A projection objective for microlithography includes at least one optical assembly with optical elements which are disposed between an object plane and an image plane. The optical assembly includes at least one optical terminal element, which is disposed close to the image plane. A first immersion liquid is disposed on the image oriented surface of the optical terminal element. A second immersion liquid is disposed on the object oriented surface of the optical terminal element. The object oriented surface includes a first surface section for the imaging light to enter into the terminal element, and the image oriented surface includes a second surface portion for the imaging light to exit from the terminal element.
摘要:
A method for calibrating an apparatus for the position measurement of measurement structures on a lithography mask comprises the following steps: qualifying a calibration mask comprising diffractive structures arranged thereon by determining positions of the diffractive structures with respect to one another by means of interferometric measurement, determining positions of measurement structures arranged on the calibration mask with respect to one another by means of the apparatus, and calibrating the apparatus by means of the positions determined for the measurement structures and also the positions determined for the diffractive structures.
摘要:
The disclosure relates to a microlithographic projection exposure apparatus and a microlithographic projection exposure apparatus, as well as related components, methods and articles made by the methods. The microlithographic projection exposure apparatus includes an illumination system and a projection objective. The illumination system can illuminate a mask arranged in an object plane of the projection objective. The mask can have structures which are to be imaged. The method can include illuminating a pupil plane of the illumination system with light. The method can also include modifying, in a plane of the projection objective, the phase, amplitude and/or polarization of the light passing through that plane. The modification can be effected for at least two diffraction orders in mutually different ways. A mask-induced loss in image contrast obtained in the imaging of the structures can be reduced compared to a method without the modification.