A catadioptric projection objective has a multiplicity of lenses and at least one concave mirror, and also two deflection mirrors in order to separate a partial beam path running from the object field to the concave mirror from the partial beam path running from the concave mirror to the image field. The deflection mirrors are tilted relative to the optical axis of the projection objective about tilting axes running parallel to a first direction (x-direction). The first deflection mirror is arranged in optical proximity to a first field plane and the second deflection mirror is arranged in optical proximity to a second field plane, which is optically conjugate with respect to the first field plane. A displacement device for the synchronous displacement of the deflection mirrors is provided. The deflection mirrors have different local distributions of their reflection properties in first and second reflection regions, respectively.

An exposure apparatus exposes a substrate with illumination light via a liquid. A liquid immersion member of the exposure apparatus has a lower surface, a plurality of collection ports, and a plurality of supply ports. The lower surface has an opening through which illumination light passes. The collection ports are arranged at the lower surface to surround the opening, and the supply ports are arranged at the lower surface and between the opening and the collection ports to surround the opening, such that the liquid is supplied via the supply ports onto the substrate while the substrate is arranged opposite to a plane-convex lens of a projection optical system and such that the liquid is collected via the collection ports from the substrate.

A prism rotation adjustment mechanism, a photolithographic exposure system and a photolithography tool are disclosed. The prism rotation adjustment mechanism includes a frame (200), a flexible mechanism (100) and an actuation mechanism. The flexible mechanism (100) includes a fixing component (110), an actuating component (120), a connecting component (130) and a swinging component (140) that are flexibly articulated in a sequence. The fixing component (110) is fixed to the frame (200). The actuation mechanism is fixed to the frame (200) and coupled to the actuating component (120). On the swinging component (140) are secured a prism wherein an axis of articulation between the swinging component (140) and the fixing component (110) is in correspondence with a rotational center of the prism. The flexible mechanism of the prism rotation adjustment mechanism is a quadrilateral flexibly-articulated assembly, in which, when driven by the actuation mechanism, the actuating component can convert translational movement into rotational movement, allowing the control of the rotational movement to be more accurate and hence improving the rotational control accuracy of the prisms. Moreover, the axis of articulation between the swinging component and the fixing component provides a stable axis for the prisms to rotate thereabout, avoiding crosstalk during the rotation and hence additionally improving the prism rotation control accuracy.

A method of providing a catadioptric projection includes: providing a first partial objective for imaging an object field onto a first real intermediate image; providing a second partial objective for imaging the first real intermediate image onto a second real intermediate image, in which the second partial objective includes a concave mirror; providing a third partial objective for imaging the second intermediate image onto an image field, the third partial objective including an aperture stop; providing a first folding mirror and a second folding mirror; and providing an antireflection coating onto a surface of at least one lens that is directly adjacent to the concave mirror or that is separate from the concave mirror by a single lens, in which the antireflection coating is designed to have reflectivity of less than 0.2% for a wavelength between 150 nm and 250 nm and for an angle-of-incidence range between 0 and 30.

A projection objective of a microlithographic projection exposure apparatus contains a plurality of optical elements arranged in N>2 successive sections A.sub.1 to A.sub.N of the projection objective which are separated from one another by pupil planes or intermediate image planes. According to the invention, in order to correct a wavefront deformation, at least two optical elements each have an optically active surface locally reprocessed aspherically. A first optical element is in this case arranged in one section A.sub.j, j=1 . . . N and a second optical element is arranged in another section A.sub.k, k=1 . . . N, the magnitude difference |kj| being an odd number.

Techniques are disclosed for magnification compensation and/or beam steering in optical systems. An optical system may include a lens system to receive first radiation associated with an object and direct second radiation associated with an image of the object toward an image plane. The lens system may include a set of lenses, and an actuator system to selectively adjust the set of lenses to adjust a magnification associated with the image symmetrically along a first and a second direction. The lens system may also include a beam steering lens to direct the first radiation to provide the second radiation. In some examples, the lens system may also include a second set of lenses, where the actuator system may also selectively adjust the second set of lenses to adjust the magnification along the first or the second direction. Related methods are also disclosed.

An imaging apparatus for exposing a pattern onto a substrate has an illumination source that is energizable to generate a polarized exposure illumination beam of an actinic wavelength range and a mask disposed to impart the pattern to the polarized exposure illumination beam. A polarization beam splitter defines an illumination path that conveys the generated polarized exposure illumination beam through a quarter wave plate and plano-convex lens and toward a concave mirror and further conveys a reflected exposure illumination beam from the concave mirror toward an exposure plane for exposing the imparted pattern onto the substrate. The exposure plane is defined by the concave mirror, the plano convex lens, and the polarization beam splitter.

A catadioptric projection objective for images an object field onto an image field via imaging radiation. The projection objective includes at least one reflective optical component and a measuring device. The reflective optical component, during the operation of the projection objective, reflects a first part of the imaging radiation and transmits a second part of the imaging radiation. The reflected, first part of the imaging radiation at least partly contributes to the imaging of the object field. The transmitted, second part of the imaging radiation is at least partly fed to a measuring device. This allows a simultaneous exposure of the photosensitive layer at the location of the image field with the imaging radiation and monitoring of the imaging radiation with the aid of the measuring device.

The present invention provides a projection optical system including a first concave reflecting surface, a first convex reflecting surface, a second concave reflecting surface, and a third concave reflecting surface, wherein the first concave reflecting surface, the first convex reflecting surface, the second concave reflecting surface, and the third concave reflecting surface are arranged such that light from an object plane forms an image on an image plane by being reflected by the first concave reflecting surface, the first convex reflecting surface, the second concave reflecting surface, the first convex reflecting surface, and the third concave reflecting surface in an order named.

A method for manufacturing an integrated circuit includes scanning a wafer with respect to a catadioptric projection objective and imaging a pattern on a mask onto a wafer while scanning the wafer. The imaging includes illuminating the mask with radiation; imaging, using the radiation, the pattern into a first intermediate image, the first intermediate image to a second intermediate image, and the second intermediate image into an image field arranged in an image surface where the wafer is arranged; and, manipulating one or more of optical elements while scanning the wafer to reduce errors in the image at the image field. A concave mirror arranged in a region of a pupil surface reflects the radiation. The projection objective also includes mirrors to deflect the radiation from the object field towards the concave mirror and to deflect the radiation from the concave mirror towards the image field. The deflection mirrors are mechanically coupled to a displacement device arranged to displace the first and second deflection mirrors.