An illumination system includes a plurality of pixels (or spots) that are (or may be) configured in one or more polarization configuration types. The pixels of the illumination system may be configured to promote particular types of polarization (e.g., transverse electric (TE) polarization, transvers magnetic (TM) polarization) to increase pattern contrast while achieving suitable exposure operation throughput. Moreover, the pixels of the pixels of the illumination system may be configured to achieve free-form (arbitrary or freely-configurable) polarization, which permits the polarization of radiation to be tailored to particular exposure operation patterns and other parameters.

An illumination system for an EUV projection lithographic projection exposure apparatus comprises an EUV light source, which generates an output beam of EUV illumination light with a predetermined polarization state. An illumination optical unit guides the output beam along an optical axis, as a result of which an illumination field in a reticle plane is illuminated by the output beam. The light source comprises an electron beam supply device, an EUV generating device and a polarization setting device. The EUV generating device is supplied with an electron beam by the electron beam supply device. The polarization setting device exerts an adjustable deflecting effect on the electron beam for setting the polarization of the output beam. This results in an illumination system, which operates on the basis of an electron beam-based EUV light source and provides an output beam, which is improved for a resolution-optimized illumination.

A method for displacing an optical component is disclosed, in which the electrical power maximally required when displacing the component is less than the sum of the maximum electrical powers of the at least two actuators used for the displacement.

A simulation apparatus has: a first processing part configured to obtain a value of a parameter in a first set relating to the forming of the pattern; a second processing part configured to obtain a value of a parameter in a second set that is at least partially same as the parameter in the first set and relating to the forming of the pattern; and an integration processing part configured to evaluate, based on the value of the parameter in the first set and the value of the parameter in the second set, a state of the pattern formed on the substrate and a forming condition when the pattern is formed, and to determine based on the result of the evaluation whether or not to make at least one of the first processing part and the second processing part recalculate the value of the parameter in the corresponding set.

A support device for an optical apparatus is disclosed. The support device includes first and second support elements. The support device also includes first and second flexure bearings. The first flexure bearing and the second flexure bearing each connect the first support element and the second support element to one another in a thermally conductive manner and hold the first support element in a manner movable in at least one first direction relative to the second support element. Spring forces generated by the first flexure bearing and the second flexure bearing partly or completely cancel one another out in the case of a movement of the first support element relative to the second support element in the first direction.

An illumination optical unit for EUV projection lithography illuminates an illumination field with illumination light from a light source. A first facet mirror of the illumination optical unit has a plurality of first facets for the reflective guidance of partial beams of a beam of the EUV illumination light. Disposed downstream of the first facet mirror is a second facet mirror with a plurality of second facets for further reflective guidance of the partial beams. As a result of this, the reflective beam guidance that the two facets predetermines object field illumination channels, by which the whole object field is illuminable by the illumination light in each case and to which exactly one first facet and exactly one second facet is assigned in each case.

An illumination optical unit for EUV projection lithography includes a field facet mirror and a pupil facet mirror. A correction control device, which is used for the controlled displacement of at least some field facets that are usable as correction field facets, which are signal connected to displacement actuators, is embodied so that a correction displacement path for the correction field facets is so large that a respective correction illumination channel is cut off at the margin by the correction pupil facet so that the illumination light partial beam is not transferred in the entirety thereof from the correction pupil facet into the object field.

A facet mirror, such as for use as an optical component in a projection exposure apparatus for EUV microlithography, includes at least two mirror modules having individual mirrors and mirror module surfaces and at least on one side a non-reflective edge region and a module edge. Adjacent individual mirrors in the mirror modules are a distance from each other that is less than half the width of the non-reflective edge region. The at least two adjacent module edges of adjacent mirror modules are offset with respect to each other by a height h along the surface normal of one of the two mirror module surfaces.

An illumination system of a microlithographic projection exposure apparatus comprises an optical integrator having a plurality of light entrance facets and a beam deflection array of reflective or transparent beam deflecting elements. Each beam deflecting element is configured to illuminate a spot on the optical integrator at a position that is variable by changing a deflection angle produced by the beam deflecting element. The illumination system further comprises a control unit which is configured to control the beam deflection elements in such a manner that a light pattern assembled from the spots on at least one of the light entrance facets is varied in response to an input command that a field dependency of the angular irradiance distribution in a mask plane shall be modified.

An optical component comprising a mirror array having a multiplicity of mirror elements, which each have at least one degree of freedom of displacement, and which are each connected to at least one actuator for displacement, has a multiplicity of local regulating devices for damping oscillations of the mirror elements, wherein each of the regulating devices in each case has at least one capacitive sensor having at least one moveable electrode and at least one electrode arranged rigidly relative to the carrying structure.