Abstract: An optical module includes a chamber capable of being evacuated and a mirror in the chamber. The mirror includes a plurality of individual mirrors. Each individual mirror includes: a mirror body including a reflection face; a support structure; and a thermally conductive portion that mechanically connects the support structure to the mirror body. For at least one individual mirror, the thermally conductive portion includes a plurality of thermally conductive strips arranged radially, adjacent thermally conductive strips being separated from each other, and each of the plurality of thermally conductive strips connecting the mirror body to the support structure. For at least one individual mirror, an actuator is associated with the mirror body, the actuator being configured to displace the mirror body relative to the support structure in at least one degree of freedom.

Abstract: The invention relates to a damping arrangement for dissipating oscillation energy of an element in a system, more particularly in a microlithographic projection exposure apparatus, comprising an absorber mass, which is mounted via a stable mounting with respect to the element, wherein the absorber mass is arranged in a cavity present within the element and is at least partly surrounded by a fluid situated in the cavity, wherein a mass-spring system is formed by the absorber mass, the system damping a translational movement component of an oscillation of the element that exists at the linking point of the absorber mass, and wherein the stable mounting is formed by a rheological fluid that is electrically controllable or controllable via electric or magnetic fields.

Abstract: A projection illumination installation for EUV microlithography includes an EUV synchrotron light source for producing EUV used light. An object field is illuminated with the used light using illumination optics. The object field is mapped into an image field using projection optics. A scanning device is used to illuminate the object field by deflecting the used light in sync with a projection illumination period. The result is a projection illumination installation in which the output power from an EUV synchrotron light source can be used as efficiently as possible for EUV projection illumination.

Abstract: A method is provided for producing a support structure including an at least partly reversibly deformable base body with a cut-out. A component can be held in the cut-out by friction. The method includes machining the base body in the braced state, wherein an opening is introduced into the base body and/or widened. The opening is deformed when the deformation force is removed such that the cut-out is formed. The opening is formed such that the application of a joining force makes it possible to deform the cut-out such that a component to be held can be introduced into the deformed cut-out with a clearance fit and an at least partial recovery of the deformed cut-out brings about a pressure contact between the held component and the cut-out in predefined circumferential regions. A method is disclosed for connecting a component to a support structure. A method is disclosed for connecting a component to an assembly including a support structure with a cut-out and a component.

Abstract: A device serves for controlling temperature of an optical element provided in vacuum atmosphere. The device has a cooling apparatus having a radiational cooling part, arranged apart from the optical element, for cooling the optical element by radiation heat transfer. A controller serves for controlling temperature of the radiational cooling part. Further, the device comprises a heating part for heating the optical element. The heating part is connected to the controller for controlling the temperature of the heating part. The resulting device for controlling temperature in particular can be used with an optical element in a EUV microlithography tool leading to a stable performance of its optics.

Abstract: A device serves for controlling temperature of an optical element provided in vacuum atmosphere. The device has a cooling apparatus having a radiational cooling part, arranged apart from the optical element, for cooling the optical element by radiation heat transfer. A controller serves for controlling temperature of the radiational cooling part. Further, the device comprises a heating part for heating the optical element. The heating part is connected to the controller for controlling the temperature of the heating part. The resulting device for controlling temperature in particular can be used with an optical element in a EUV microlithography tool leading to a stable performance of its optics.

Abstract: The invention relates to an arrangement for actuating an element in an optical system of a projection exposure apparatus, wherein the projection exposure apparatus has a carrying frame, comprising at least one actuator for exerting controllable forces on the element, wherein the actuator has a first actuator part, which is coupled to the carrying frame via at least one mechanical filter, and a second actuator part, which is mechanically coupled directly to the carrying frame, and wherein the loading on the first actuator part is at least partly relieved by the second actuator part when forces are exerted on the element.

Abstract: Illumination optics for EUV microlithography guide an illumination light bundle from a radiation source to an object field with an extension ratio between a longer field dimension and a shorter field dimension, where the ratio is considerably greater than 1.

Abstract: An EUV lithography system 1 comprises an EUV beam path and a monitor beam path 51. The EUV beam path comprises a mirror system 13, which has a base and a multiplicity of mirror elements 17 having concave mirror surfaces, the orientation of which relative to the base is respectively adjustable. The monitor beam path 51 comprises at least one monitor radiation source 53, a screen 71, the mirror system 13, which is arranged in the monitor beam path 51 between the monitor radiation source 53 and the screen 71, and a spatially resolving detector 77. In this case, each of a plurality of the mirror elements generates an image of the monitor radiation source in an image plane assigned to the respective mirror elements, distances B between the image planes assigned to the mirror elements and the screen have a maximum distance, distances A between each of the plurality of mirror elements and the image plane assigned to it have a minimum distance, and the maximum distance B is less than half of the minimum distance A.

Abstract: The disclosure relates to an optical element configure to at least partial spatially resolve correction of a wavefront aberration of an optical system (e.g., a projection exposure apparatus for microlithography) to which optical radiation can be applied, as well as related systems and methods.

Abstract: The disclosure concerns an arrangement for mirror temperature measurement and/or thermal actuation of a mirror in a microlithographic projection exposure apparatus. The mirror has an optical effective surface and at least one access passage extending from a surface of the mirror, that does not correspond to the optical effective surface, in the direction of the effective surface. The arrangement is designed for mirror temperature measurement and/or thermal actuation of the mirror via electromagnetic radiation which is propagated along the access passage. The electromagnetic radiation is reflected a plurality of times within the access passage.

Abstract: A device serves for controlling temperature of an optical element provided in vacuum atmosphere. The device has a cooling apparatus having a radiational cooling part, arranged apart from the optical element, for cooling the optical element by radiation heat transfer. A controller serves for controlling temperature of the radiational cooling part. Further, the device comprises a heating part for heating the optical element. The heating part is connected to the controller for controlling the temperature of the heating part. The resulting device for controlling temperature in particular can be used with an optical element in a EUV microlithography tool leading to a stable performance of its optics.

Abstract: The disclosure relates to an optical correction device with thermal actuators for influencing the temperature distribution in the optical correction device. The optical correction device is constructed from at least two partial elements which differ with regard to their ability to transport heat. Furthermore, the disclosure relates to methods for influencing the temperature distribution in an optical element.

Abstract: The disclosure relates to an optical apparatus including a light source that emits light in the form of light pulses having a pulse frequency, and including at least one optical element. The disclosure also relates to a projection exposure machine including a pulsed light source and a projection objective, and to a method for modifying the imaging behavior of such an apparatus, such as in a projection exposure machine.

Abstract: An optical module is used to guide an EUV radiation beam. The optical module has a chamber that can be evacuated and at least one mirror accommodated in the chamber. The mirror has a plurality of individual mirrors, the reflection faces of which complement one another to form an overall mirror reflection face. A support structure is in each case mechanically connected via a thermally conductive portion to a mirror body of the respective individual mirror. At least some of the mirror bodies have an associated actuator for the predetermined displacement of the mirror body relative to the support structure in at least one degree of freedom. The thermally conductive portions are configured to dissipate a thermal power density of at least 1 kW/m2 absorbed by the mirror bodies to the support structure.

Abstract: A device serves for controlling temperature of an optical element provided in vacuum atmosphere. The device has a cooling apparatus having a radiational cooling part, arranged apart from the optical element, for cooling the optical element by radiation heat transfer. A controller serves for controlling temperature of the radiational cooling part. Further, the device comprises a heating part for heating the optical element. The heating part is connected to the controller for controlling the temperature of the heating part. The resulting device for controlling temperature in particular can be used with an optical element in a EUV microlithography tool leading to a stable performance of its optics.

Abstract: A control method is provided for controlling a heating of a thermal optical element, the thermal optical element having a matrix of heater elements. The method includes stabilizing a nominal temperature of the thermal optical element with a feedback loop to control the heating of heater elements; providing a desired temperature profile of the thermal optical element by a set point signal; determining a feedforward control of the heater elements from the set point signal; and forwardly feeding an output of the feedforward control into the feedback loop.

Abstract: A method is provided for producing a support structure including an at least partly reversibly deformable base body with a cut-out. A component can be held in the cut-out by friction. The method includes machining the base body in the braced state, wherein an opening is introduced into the base body and/or widened. The opening is deformed when the deformation force is removed such that the cut-out is formed. The opening is formed such that the application of a joining force makes it possible to deform the cut-out such that a component to be held can be introduced into the deformed cut-out with a clearance fit and an at least partial recovery of the deformed cut-out brings about a pressure contact between the held component and the cut-out in predefined circumferential regions. A method is disclosed for connecting a component to a support structure. A method is disclosed for connecting a component to an assembly including a support structure with a cut-out and a component.

Abstract: A device serves for controlling temperature of an optical element provided in vacuum atmosphere. The device has a cooling apparatus having a radiational cooling part, arranged apart from the optical element, for cooling the optical element by radiation heat transfer. A controller serves for controlling temperature of the radiational cooling part. Further, the device comprises a heating part for heating the optical element. The heating part is connected to the controller for controlling the temperature of the heating part. The resulting device for controlling temperature in particular can be used with an optical element in a EUV microlithography tool leading to a stable performance of its optics.

Abstract: A control method is provided for controlling a heating of a thermal optical element, the thermal optical element having a matrix of heater elements. The method includes stabilizing a nominal temperature of the thermal optical element with a feedback loop to control the heating of heater elements; providing a desired temperature profile of the thermal optical element by a set point signal; determining a feedforward control of the heater elements from the set point signal; and forwardly feeding an output of the feedforward control into the feedback loop.