Abstract: Microlithographic illumination system includes individually drivable elements to variably illuminate a pupil surface of the system. Each element deviates an incident light beam based on a control signal applied to the element. The system also includes an instrument to provide a measurement signal, and a model-based state estimator configured to compute, for each element, an estimated state vector based on the measurement signal. The estimated state vector represents: a deviation of a light beam caused by the element; and a time derivative of the deviation. The illumination system further includes a regulator configured to receive, for each element: a) the estimated state vector; and b) target values for: i) the deviation of the light beam caused by the deviating element; and ii) the time derivative of the deviation.

Abstract: A projection exposure apparatus for microlithography comprises illumination optics for illuminating object field points of an object field in an object plane is disclosed. The illumination optics have, for each object field point of the object field, an exit pupil associated with the object point, where sin(?) is a greatest marginal angle value of the exit pupil. The illumination optics include a multi-mirror array that includes a plurality of mirrors to adjust an intensity distribution in exit pupils associated to the object field points. The illumination optics further contain at least one optical system to temporally stabilize the illumination of the multi-mirror array so that, for each object field point, the intensity distribution in the associated exit pupil deviates from a second adjusted intensity distribution in the associated exit pupil by less than 0.1 in at least one of an inner ? or an outer ?.

Abstract: An optical raster element for an illumination system of a microlithographic projection exposure apparatus includes an array of refractive optical elements extending on a planar or curved surface. At least two of the optical elements are arranged side by side along a reference direction with a pitch of less than 2 mm. They have a height perpendicular to the surface of less than 50 ?m and a surface profile along the reference direction which includes a central section, two transition sections adjacent the central section and two end sections adjacent the transition sections. The curvatures in the two transition sections are greater than the curvatures in the central section and the end sections. The optical raster element is intended for being used as a first channel plate in an optical integrator (honeycomb condenser) and can reduce the maximum light intensities occurring in or behind the second channel plate.

Abstract: A projection exposure apparatus for microlithography comprises illumination optics for illuminating object field points of an object field in an object plane is disclosed. The illumination optics have, for each object field point of the object field, an exit pupil associated with the object point, where sin(?) is a greatest marginal angle value of the exit pupil. The illumination optics include a multi-mirror array that includes a plurality of mirrors to adjust an intensity distribution in exit pupils associated to the object field points. The illumination optics further contain at least one optical system to temporally stabilize the illumination of the multi-mirror array so that, for each object field point, the intensity distribution in the associated exit pupil deviates from a second adjusted intensity distribution in the associated exit pupil by less than 0.1 in at least one of an inner ? or an outer ?.

Abstract: A microlithographic projection exposure apparatus includes an optical surface and a measurement device which measures a parameter related to the optical surface at a plurality of separated areas on the optical surface. The measurement device includes an illumination unit which directs individual measuring light beams towards the areas on the optical surface. Each measuring light beam illuminates at least a portion of an area, which is associated with the measuring light beam, and at least a portion of an adjacent area which is not associated with the measuring light beam. A detector unit measures a property for each measuring light beam after it has interacted with the optical surface.

Abstract: An illumination system of a microlithographic projection exposure apparatus comprises a light source which is configured to produce projection light (PL), a pupil plane and a diffractive optical element that is arranged between the light source and the pupil plane such that an irradiance distribution of projection light (PL) in the pupil plane depends on the position of a field that is illuminated by the projection light (PL) on the diffractive optical element. The illumination system further comprises an optical imaging system-that is arranged between the light source and the diffractive optical element. The optical imaging system ensures that changes of the direction and divergence of the projection light (PL) emitted by the light source have no substantial effect on the position and size of the field which is illuminated on the diffractive optical element by the projection light (PL).

Abstract: An illumination system of a micro-lithographic projection exposure apparatus is provided, which is configured to illuminate a mask positioned in a mask plane. The system includes a pupil shaping optical subsystem and illuminator optics that illuminate a beam deflecting component. For determining a property of the beam deflecting component, an intensity distribution in a system pupil surface of the illumination system is determined. Then the property of the beam deflecting component is determined such that the intensity distribution produced by the pupil shaping subsystem in the system pupil surface approximates the intensity distribution determined before. At least one of the following aberrations are taken into account in this determination: (i) an aberration produced by the illuminator optics; (ii) an aberration produced by the pupil shaping optical subsystem; (iii) an aberration produced by an optical element arranged between the system pupil surface and the mask plane.

Abstract: A method for setting an illumination geometry for an illumination optical unit for EUV projection lithography is disclosed. The method includes defining a desired illumination geometry, followed by varying tilting angles of individual mirrors of the a facet mirror within one and the same individual-mirror group. In a first tilting position, the individual mirrors are assigned via a first group-mirror illumination channel to a first facet of a second facet mirror. In at least one further tilting position, the individual mirrors are assigned either via a further illumination channel to a further facet of the second facet mirror or to a switch-off illumination channel. The tilting angle variation is carried out until an actual illumination geometry corresponds to the desired illumination geometry within predefined tolerances.

Abstract: An illumination system of a micro-lithographic projection exposure apparatus is provided, which is configured to illuminate a mask positioned in a mask plane. The system includes a pupil shaping optical subsystem and illuminator optics that illuminate a beam deflecting component. For determining a property of the beam deflecting component, an intensity distribution in a system pupil surface of the illumination system is determined. Then the property of the beam deflecting component is determined such that the intensity distribution produced by the pupil shaping subsystem in the system pupil surface approximates the intensity distribution determined before. At least one of the following aberrations are taken into account in this determination: (i) an aberration produced by the illuminator optics; (ii) an aberration produced by the pupil shaping optical subsystem; (iii) an aberration produced by an optical element arranged between the system pupil surface and the mask plane.

Abstract: An illumination system of a microlithographic projection exposure apparatus includes a light source to produce projection light beam, and a first and a second diffractive optical element between the light source and a pupil plane of the illumination system. The diffractive effect produced by each diffractive optical element depends on the position of a light field that is irradiated by the projection light on the diffractive optical elements. A displacement mechanism changes the mutual spatial arrangement of the diffractive optical elements. In at least one of the mutual spatial arrangements, which can be obtained with the help of the displacement mechanism, the light field extends both over the first and the second diffractive optical element. This makes it possible to produce in a simple manner continuously variable illumination settings.

Abstract: The present invention relates to an apparatus for influencing a light beam arrangement comprising a plurality of light beams (4) arranged alongside one another, wherein provision is made of at least one optical element (5, 15, 25) which is movable transversely with respect to the light beams and by which the light beams can be influenced if the light beams pass through the optical element, and which has at least one light-absorbing region (9, 19, 29), wherein the apparatus comprises a drive device for the optical element, a measuring device for detecting the light of the light beam and a control unit, wherein the control unit is designed such that the drive device is controlled in a manner dependent on the position of the light-absorbing region.

Abstract: An illumination system of a microlithographic projection exposure apparatus has a pupil surface and an essentially flat arrangement of desirably individually drivable beam deviating elements for variable illumination of the pupil surface. Each beam deviating element allows deviation of a projection light beam incident on it to be achieved as a function of a control signal applied to the beam deviating element. A measurement illumination instrument directs a measurement light beam, independent of the projection light beams, onto a beam deviating element. A detector instrument records the measurement light beam after deviation by the beam deviating element. An evaluation unit determines the deviation of the projection light beam from measurement signals provided by the detector instrument.

Abstract: Microlithographic illumination system includes individually drivable elements to variably illuminate a pupil surface of the system. Each element deviates an incident light beam based on a control signal applied to the element. The system also includes an instrument to provide a measurement signal, and a model-based state estimator configured to compute, for each element, an estimated state vector based on the measurement signal. The estimated state vector represents: a deviation of a light beam caused by the element; and a time derivative of the deviation. The illumination system further includes a regulator configured to receive, for each element: a) the estimated state vector; and b) target values for: i) the deviation of the light beam caused by the deviating element; and ii) the time derivative of the deviation.

Abstract: A microlithographic projection exposure apparatus includes an optical surface and a measurement device which measures a parameter related to the optical surface at a plurality of separated areas on the optical surface. The measurement device includes an illumination unit which directs individual measuring light beams towards the areas on the optical surface. Each measuring light beam illuminates at least a portion of an area, which is associated with the measuring light beam, and at least a portion of an adjacent area which is not associated with the measuring light beam. A detector unit measures a property for each measuring light beam after it has interacted with the optical surface.

Abstract: The present invention relates to an apparatus for influencing a light beam arrangement comprising a plurality of light beams (4) arranged alongside one another, wherein provision is made of at least one optical element (5, 15, 25) which is movable transversely with respect to the light beams and by which the light beams can be influenced if the light beams pass through the optical element, and which has at least one light-absorbing region (9, 19, 29), wherein the apparatus comprises a drive device for the optical element, a measuring device for detecting the light of the light beam and a control unit, wherein the control unit is designed such that the drive device is controlled in a manner dependent on the position of the light-absorbing region.

Abstract: A microlithographic projection exposure apparatus includes an optical surface, which may be formed by a plurality of micro-mirrors, and a measurement device which is configured to measure a parameter related to the optical surface at a plurality of locations. The measurement device includes an illumination unit with a plurality of illumination members, each having a light exit facet. An optical imaging system establishes an imaging relationship between an object plane in which at least two light exit facets are arranged, and an image plane which at least substantially coincides with the optical surface. A detector unit measures the property of measuring light after it has interacted with the optical surface, and an evaluation unit determines the surface related parameter for each of the locations on the basis of the properties determined by the detector unit.

Abstract: In a projection exposure method for the exposure of a radiation-sensitive substrate arranged in the region of an image surface of a projection objective with at least one image of a pattern of a mask arranged in the region of an object surface of the projection objective, laser radiation having a spectral intensity distribution I(?) dependent on the angular frequency ? is used. The laser radiation is characterized by an aberration parameter ? in accordance with: ? := ? I ? ( ? ) ? ? 2 ? ? ? ? I ? ( ? ) ? ? ? and a coherence time ? in accordance with: ? = ? I ? ( ? ) 2 ? ? ? [ ? I ? ( ? ) ? ? ? ] 2 The laser radiation is introduced into an illumination system for generating an illumination radiation directed onto the mask, and the pattern is imaged onto the substrate with the aid of a projection objective. The spectral intensity distribution is set so that ??2?0.3.

Abstract: An optical raster element for an illumination system of a microlithographic projection exposure apparatus includes an array of refractive optical elements extending on a planar or curved surface. At least two of the optical elements are arranged side by side along a reference direction with a pitch of less than 2 mm. They have a height perpendicular to the surface of less than 50 ?m and a surface profile along the reference direction which includes a central section, two transition sections adjacent the central section and two end sections adjacent the transition sections. The curvatures in the two transition sections are greater than the curvatures in the central section and the end sections. The optical raster element is intended for being used as a first channel plate in an optical integrator (honeycomb condenser) and can reduce the maximum light intensities occurring in or behind the second channel plate.

Abstract: A projection exposure apparatus for microlithography comprises illumination optics for illuminating object field points of an object field in an object plane is disclosed. The illumination optics have, for each object field point of the object field, an exit pupil associated with the object point, where sin(?) is a greatest marginal angle value of the exit pupil. The illumination optics include a multi-mirror array that includes a plurality of mirrors to adjust an intensity distribution in exit pupils associated to the object field points.

Abstract: A projection exposure apparatus for microlithography comprises illumination optics for illuminating object field points of an object field in an object plane is disclosed. The illumination optics have, for each object field point of the object field, an exit pupil associated with the object point, where sin(?) is a greatest marginal angle value of the exit pupil. The illumination optics include a multi-mirror array that includes a plurality of mirrors to adjust an intensity distribution in exit pupils associated to the object field points.