An illumination intensity correction device serves for predefining an illumination intensity over an illumination field of a lithographic projection exposure apparatus. The correction device has a plurality of bar-shaped individual stops arranged alongside one another and having bar axes arranged parallel to one another, which are arranged in a manner lined up alongside one another transversely with respect to the bar axes. The individual stops are displaceable into a predefined intensity correction displacement position at least along their respective bar axis with the aid of a displacement drive individually for the purpose of predefining an intensity correction of an illumination of the illumination field.

Systems, apparatuses, and methods are provided for adjusting illumination slit uniformity in a lithographic apparatus. An example method can include determining whether an exposure field for a wafer exposure operation is less than a maximum exposure field of a uniformity correction system. In response to determining that the exposure field is less than the maximum exposure field, the example method can include modifying illumination slit uniformity calibration data associated with the maximum exposure field to generate modified illumination slit uniformity calibration data associated with the exposure field. Subsequently, the example method can include determining an optimal position of a finger assembly of the uniformity correction system based on the modified illumination slit uniformity calibration data.

The invention relates to a dual stage lithographic apparatus, wherein two substrate stages are constructed and arranged for mutual cooperation in order to perform a joint scan movement. The joint scan movement brings the lithographic apparatus from a first configuration, wherein immersion liquid is confined between a first substrate held by the first stage of the stages and a projection system of the apparatus, to a second configuration, wherein the immersion liquid is confined between a second substrate held by the second stage of the two stages and the projection system, such that during the joint scan movement the liquid is essentially confined within the space with respect to the projection system.

Projection exposure methods, systems, sub-systems and components are disclosed. Methods can include performing a first exposure to image a first sub-pattern of the pattern, where the first sub-pattern includes a plurality of first features extending in a first direction and spaced apart essentially periodically at a predominant periodicity length P in a second direction perpendicular to the first direction. The first exposure can be performed using a multipolar illumination mode that includes at least one substantially dipolar intensity distribution having two illumination poles positioned on a pole orientation axis substantially parallel to the second direction and spaced apart from each other.

A lithographic system including a lithographic apparatus with an anamorphic projection system, and a radiation source configured to generate an EUV radiation emitting plasma at a plasma formation location, the EUV radiation emitting plasma having an elongate form in a plane substantially perpendicular to an optical axis of the radiation source.

An abnormality detection apparatus for detecting an abnormal operation in a shutter apparatus configured to block light includes one or more memories, and one or more processors that cooperate with the one or more memories to detect the abnormal operation using an abnormality detection model that outputs determination data for detecting the abnormal operation in a case where information about measurement data on the shutter apparatus is input to the abnormality detection model.

A patterning device for a lithographic apparatus arranged to project a pattern from the patterning device onto a substrate, the patterning device comprising: an imaging area having opposing first sides extending parallel to a scanning direction of the lithographic apparatus and opposing second sides extending perpendicularly to the scanning direction, and at least one sensing mark located adjacent to at least one second side of the imaging area; wherein the at least one sensing mark is located a predetermined distance in the scanning direction away from the at least one second side of the imaging area and extends a width in the scanning direction such that the at least one sensing mark, when projected onto the substrate, fits within a scribe line on the substrate.

The invention relates to a photolithographic illuminator device including: a light beam source, a condenser (5), an optical homogenizing system (4) including at least one microlens array, said system being arranged upstream from the condenser, and a shutter (3) arranged at the object focal point of the optical homogenizing system, the illuminator being characterized in that same further comprises a network of aperture diaphragms (8) arranged in the Fourier transform plane of the shutter plane (3). The invention likewise relates to a photolithographic device including such an illuminator.

An illumination system of a microlithographic projection exposure apparatus includes a pupil forming unit directing light on a spatial light modulator that transmits or reflects impinging light in a spatially resolved manner. An objective images a light exit surface of the spatial light modulator on light entrance facets of an optical integrator so that an image of an object area on the light exit surface completely coincides with one of the light entrance facets. The pupil forming unit and the spatial light modulator are controlled so that the object area is completely illuminated by the pupil forming unit and projection light associated with a point in the object area is at least partially and variably prevented from impinging on the one of the light entrance facets.

Projection exposure methods, systems, sub-systems and components are disclosed. Methods can include performing a first exposure to image a first sub-pattern of the pattern, where the first sub-pattern includes a plurality of first features extending in a first direction and spaced apart essentially periodically at a predominant periodicity length P in a second direction perpendicular to the first direction. The first exposure can be performed using a multipolar illumination mode that includes at least one substantially dipolar intensity distribution having two illumination poles positioned on a pole orientation axis substantially parallel to the second direction and spaced apart from each other.