A mirror mounting member is formed of a ceramic structure with a prismatic or angular cylindrical shape and includes, as outer surfaces, a joining surface configured to join to a to-be-joined surface, and an inclined surface inclined relative to the joining surface. The inclined surface is a mounting surface on which is mounted a reflective film that reflects light emitted from a light source. The joining surface includes a plurality of first grooves extending in a longitudinal direction of the structure and a plurality of second grooves intersecting the first grooves. The first grooves are open at both ends, and the second grooves are sealed at an end portion located on a side where light is reflected by the reflective film.

The invention relates to a substrate exposure system comprising a frame, a substrate support module for carrying a substrate, an exposure apparatus for exposing said substrate, and adjustment assembly for adjusting the position of the exposure apparatus with respect to the substrate support module. The adjustment assembly comprises a hydraulic actuator, a hydraulic generator and a conduit, wherein the conduit interconnects said hydraulic actuator and said hydraulic generator for forming a hydraulic system. The exposure apparatus, the frame, the adjustment assembly and the substrate support module are arranged as parts of a series of mechanically linked components. A first part of said series of mechanically linked components comprises the exposure apparatus, and a second part comprises the substrate support module. Said hydraulic actuator is arranged between said first part and said second part. Preferably the hydraulic actuator comprises a first bellows and the hydraulic generator comprises a second bellows.

The disclosure pertains to an optical apparatus, in particular for microlithography, that includes an optical module, a support structure and a connection apparatus. The connection apparatus includes at least one connection unit which includes a first connector part and a second connector part. The first connector part is connected to the optical module, and the second connector part is connected to the support structure.

The disclosure provides an optical system, having a first optical control loop, which is set up to regulate a position and/or spatial orientation of a first optical element relative to a first module sensor frame, and a first module control loop, which is set up to regulate a position and/or spatial orientation of the first module sensor frame relative to a base sensor frame. Related components and methods are also provided

An active vibration isolation system with a magnetic actuator where the magnetic actuator includes a coil carrier with at least one coil which engages in a magnetic actuator without touching it so that it takes the form of a linear motor. The magnetic actuator has a magnetic shield with an opening through which the coil carrier extends into the magnet carrier.

The present disclosure relates to an extreme ultraviolet lithography, EUVL, device comprising: a reticle comprising a lithographic pattern to be imaged on a target wafer; a light-transmissive pellicle membrane mounted in front of, and parallel to, the reticle, wherein the pellicle membrane scatters transmitted light along a scattering axis; and an extreme ultraviolet, EUV, illumination system configured to illuminate the reticle through the pellicle membrane, wherein an illumination distribution provided by the EUV illumination system is asymmetric as seen in a source-pupil plane of the EUV illumination system; wherein light reflected by the reticle and then transmitted through the pellicle membrane comprises a non-scattered fraction and a scattered fraction formed by light scattered by the pellicle membrane; the EUVL device further comprising: an imaging system having an acceptance cone configured to capture a portion of the light reflected by the reticle and then transmitted through the pellicle membrane.

A stop is configured to be arranged in a constriction of an EUV illumination light beam between an EUV light source for EUV illumination light and an EUV illumination optical unit. The stop has a beam entrance section, a beam exit section and an intervening beam tube section. The entrance section has a cross section that decreases in the propagation direction of the EUV illumination light beam. The cross section of the exit section increases in the propagation direction. The cross section of the tube section is constant. An inner wall of the beam tube section is embodied as reflective for the EUV illumination light. The result is a stop that can have a defined predetermination of the illumination light beam in conjunction with a good thermal loading capacity of the stop.

A sealing device seals a first component part of a lithography apparatus vis-à-vis a multiplicity of second component parts of the lithography apparatus. The sealing device includes a multiplicity of sealing rings and a multiplicity of connection locations. The sealing rings are connected to one another with the aid of the connection locations.

A sealing device seals a first component part of a lithography apparatus vis-à-vis a multiplicity of second component parts of the lithography apparatus. The sealing device includes a multiplicity of sealing rings and a multiplicity of connection locations. The sealing rings are connected to one another with the aid of the connection locations.

A semiconductor lithography projection exposure apparatus includes a sensor reference including reference elements. The apparatus also includes an optical element, which includes a main body comprising receiving elements receiving the reference elements. The optical element further includes a referential surface that is an optically active surface of the optical element. The reference elements are arranged to determine a position and an orientation of the optical element. A method includes aligning a sensor reference with respect to a referential surface in a semiconductor lithography projection exposure apparatus.