A mirror device includes at least one electrically conductive shielding element, which forms a mechanism for producing an electric field in a region adjacent to at least one side surface and/or a rear side of a mirror body.

An illumination optical unit for EUV projection lithography serves to illuminate an object field with illumination light. A transmission optical unit images field facets in a manner superposed on one another into the object field via illumination channels, which each have assigned to them one of the field facets and one pupil facet of a pupil facet mirror. The superposition optical unit has at least two mirrors for grazing incidence, downstream of the pupil facet mirror. The mirrors for grazing incidence produce an illumination angle bandwidth of an illumination light overall beam, composed of the illumination channels, in the object field. The bandwith is smaller for a plane of incidence parallel to the object displacement direction than for a plane perpendicular thereto. The result can be an illumination optical unit, by which a projection optical unit can be adapted to a configuration of an EUV light source for the illumination light.

An illumination optical unit for projection lithography serves for illuminating an object field, in which an object to be imaged can be arranged, with illumination light. The illumination optical unit has a field facet mirror having a plurality of field facets. Furthermore, the illumination optical unit has a pupil facet mirror having a plurality of pupil facets. The field facets are imaged into the object field by a transfer optical unit. The illumination optical unit additionally has a deflection facet mirror having a plurality of deflection facets, which is arranged in the illumination beam path between the field facet mirror and the pupil facet mirror. This results in an illumination optical unit in which the illumination of the object to be imaged can be configured flexibly and can be adapted well to predefined values.

A new and useful illumination device, e.g. for a lithographic optical imaging system, is provided, and comprises a mirror array located between a radiation source and an illumination pupil. Each mirror element of the mirror array is individually steerable (controllable), and the polarization state of light from each mirror element of the mirror array can be selectively controlled, so that the illumination pupil can be filled with a distribution of light that is selectively controlled.

An illumination optical unit for microlithography illuminates an object field with illumination light. The unit includes a first facet mirror that has a plurality of first facets, and a second facet mirror that has a plurality of second facets. The unit has facet pairs which include respectively a facet of the first facet mirror and a facet of the second facet mirror which predefine a plurality of illumination channels for illuminating the object field. At least some of the illumination channels have in each case an assigned polarization element for predefining an individual polarization state of the illumination light guided in the respective illumination channel.

The invention relates to an optical system of a microlithographic projection exposure apparatus, in particular for operation in the EUV, comprising a mirror arrangement composed of a plurality of mutually independently adjustable mirror elements, and at least one polarization-influencing arrangement arranged upstream of the mirror arrangement relative to the light propagation direction, wherein the polarization-influencing arrangement has a group of first reflection surfaces and a group of second reflection surfaces, wherein the first reflection surfaces are tiltable independently of one another, and wherein, during the operation of the optical system, light reflected at respectively one of the first reflection surfaces can be directed onto the mirror arrangement via respectively a different one of the second reflection surfaces depending on the tilting of the first reflection surface.

According to one embodiment, a spatial light modulator unit is used in the illumination optical system for illuminating an illumination target surface with light from a light source and comprises: a spatial light modulator with a plurality of optical elements arrayed in a predetermined plane and controlled individually; a spatial light modulation element which applies spatial light modulation to the incident light from the light source and which makes rays of intensity levels according to positions of the respective optical elements, incident on the plurality of optical elements; and a control unit which individually controls the plurality of optical elements on the basis of information about the intensity levels of the rays incident on the respective optical elements.

The invention relates to an optical system of a microlithographic projection exposure apparatus, in particular for operation in the EUV, comprising at least one polarization-influencing arrangement having a first reflection surface and a second reflection surface, wherein the first reflection surface and the second reflection surface are arranged at an angle of 0°±10° or at an angle of 90°±10° relative to one another, wherein light incident on the first reflection surface during the operation of the optical system forms an angle of 45°±5° with the first reflection surface, and wherein the polarization-influencing arrangement is rotatable about a rotation axis running parallel to the light propagation direction of light incident on the first reflection surface during the operation of the optical system.

A microlithographic projection exposure apparatus has a measuring device, by which a sequence of measurement values can be generated, and a processing unit for processing the measurement values. The processing unit has a processing chain which includes a plurality of digital signal processors. The first digital signal processor in the processing chain is connected to the measuring device to receive the sequence of measurement values. Each subsequent digital signal processor in the processing chain is connected to a respectively preceding digital signal processor in the processing chain. The digital signal processors are programmed so that each digital signal processor processes only a fraction of the measurement values and generates processing results therefrom, and forwards the remaining fraction of the measurement values to the respective next digital signal processor in the processing chain for processing.

The disclosure provides an illumination optical unit for projection lithography, which illuminates an object field with illumination light. The illumination optical unit includes a field facet mirror with a plurality of field facets and a pupil facet mirror with a plurality of pupil facets. The field facets are imaged in the object field by a transfer optical unit. The pupil facet mirror includes a pupil facet mirror polarization section and a pupil facet mirror neutral section. The polarization section is arranged so that the illumination light is reflected in the region of a Brewster angle. The neutral section is arranged so that the illumination light is reflected in the region of a normal incidence.