A projection system (PS1) for a lithographic apparatus comprises: an optical path (100); a plurality of sensors (S1-S4); one or more actuators (A1-A4); and a controller (CN). The optical path is operable to receive an input radiation beam (Bin) and to project an output radiation beam (Bout) onto a substrate to form an image. The optical path comprises: a plurality of optical elements (M1-M4), the plurality of optical elements comprising: a first set of at least two optical elements (M1, M4) and a second set of at least one optical element (M2, M3). Each sensor is associated with one of the plurality of optical elements and is operable to determine a position of that optical element. Each actuator is associated with one of the second set of optical elements and is operable to adjust that optical element. The controller is operable to use the one or more actuators to adjust the second set of optical elements in dependence on the determined position of the first set of optical elements so as to at least partially compensate for optical aberrations and/or line-of-sight errors caused by the positions of the first set of optical elements.

As feature sizes of semiconductor chips shrink there is a need for tighter overlay between layers in a lithography process. This means more advanced and larger overlay corrections may be necessary to ensure that die are properly manufactured into chips, especially in reconstituted substrates where the die can shift in the process of creating the substrate. Systems and methods for correcting these overlay errors in a lithographic process are provided. Additional rotation (theta) and projected image size (mag) corrections can be made to correct overlay errors present in reconstituted substrates by adjusting the stage and the reticle. Furthermore, these adjustments can be made allowing site-by-site or zone-by-zone corrections instead of a one-time adjustment of the reticle chuck as has been done in the past. These corrections can alleviate some of the issues associated with fan-out wafer-level packaging (FOWLP) and fan-out panel-level packaging (FOPLP).

The invention provides a display device that allows formation of the boundary of exposure at an arbitrary position on its substrate. A display device includes: a display area; a terminal; and a wire formed between the display area and the terminal and connected to the terminal. The wire includes a first part, a second part, and a third part. The first part extends in a first direction. The second part and the third part extend in a direction different from the first direction. The first part is located between the second and third parts and includes a protruding portion protruding in a second direction perpendicular to the first direction.

A projection exposure apparatus for microlithography includes a projection lens which includes a plurality of optical elements for imaging mask structures onto a substrate during an exposure process. The projection exposure apparatus also includes at least one manipulator configured to change, as part of a manipulator actuation, the optical effects of at least one of the optical elements within the projection lens by changing a state variable of the optical element along a predetermined travel. The projection exposure apparatus further includes an algorithm generator configured to generate a travel generating optimization algorithm, adapted to at least one predetermined imaging parameter, on the basis of the at least one predetermined imaging parameter.

A method of reducing an aberration of a lithographic apparatus, the method including measuring the aberration, taking the measured aberration into account, estimating a state of the lithographic apparatus, calculating a correction using the estimated state, and applying the correction to the lithographic apparatus.

An optical element comprises a substrate and an optical surface formed on the substrate. At least one fluid-tight sealed chamber is embedded in the substrate and has a rheological fluid introduced therein for deforming the optical surface. An optical arrangement, such as an EUV lithography system, comprises at least one optical element as described above and a field generating device for generating an electromagnetic field. The electromagnetic field can be a time-varying electromagnetic field. The electromagnetic field can be a magnetic field. The electromagnetic field passes through the at least one chamber which contains the rheological fluid. A method for producing an optical element designed as described above is also provided.

Aberrations of a projection lens for microlithography can be subdivided into two classes: a first class of aberrations, which are distinguished by virtue of the fact that their future size increases by a non-negligible value after a constant time duration, independently of their current size, and a second class of aberrations, which, after reaching a threshold, only increase by a negligible value after each further time duration. An adjustment method is proposed, which adjusts these two classes of aberrations in parallel in time with one another.

An optical assembly for semiconductor lithography comprises an optical element and an actuator for deforming the optical element. The actuator is constructed from at least three sections, which include at least first and second group of sections that are controllable in each case via a controller are present. The first group serves for coarse actuation, and the second group serves for fine actuation. The controller is configured to control the groups independently of one another and the sections of a group jointly. The controller is furthermore configured to variably set the number of sections controlled jointly per group. Furthermore, the disclosure relates to a projection exposure apparatus equipped with the assembly, and to a method for controlling the optical assembly.

A projection exposure apparatus includes a projection lens, a wavefront manipulator and a wavefront measuring device for measuring a wavefront in the projection lens. The wavefront measuring device includes a Moiré grating arrangement having an object grating and an image grating which are designed to be arranged in an object plane and an image plane, respectively, of the projection lens. The object grating and the image grating are coordinated with one another in a manner true to scale in such a way as to generate a Moiré superimposition pattern from an imaging of the object grating onto the image plane and the image grating. The Moiré grating arrangement is designed in such a way as to simultaneously generate the Moiré superimposition pattern for a plurality of field points of an object field in the object plane and/or of an image field in the image plane.

Disclosed is an actuator unit for positioning an optical element, comprising a first reluctance actuator comprising a first stator part and a first mover part separated by a gap in a first direction. The first mover part is constructed and arranged to be connected to the optical element and for moving the optical element. The first stator part is constructed and arranged to exert a magnetic force on the first mover part along a first line of actuation. The first mover part is movable relative to the first stator part in the first direction. The first stator part and the first mover part are constructed and arranged such that the first line of actuation is, in operational use, moving along with the first mover part in a second direction perpendicular to the first direction, for at least a predetermined movement range of the first mover part in the second direction.