An exposure apparatus and method. The exposure apparatus includes a control system, light source system, plurality of illumination systems and plurality of projection objective lenses. The light source system is configured to emit a plurality of first illumination beams incident on the illumination systems. Each illumination system includes a variable attenuator and branch energy detector. The branch energy detector is configured to detect an illuminance level of a second illumination beam generated in the corresponding illumination system and feed it back to the control system. The control system is configured to adjust the illuminance levels of the second illumination beams in the respective illumination systems by controlling the respective variable attenuators therein. The exposure apparatus and method have improved exposure performance and allow finer and faster energy adjustments, thus enabling precise control and higher exposure accuracy.

An illumination optical system for projection lithography includes a pupil facet mirror having pupil facets. For at least some of the pupil facets which are designed as selectively reflecting pupil facets, the selectively reflecting pupil facet has a reflective coating for the illumination light, wherein a first coating area on a first part of the selectively reflecting pupil facet has a first reflectivity, a second coating area on a second part of the selectively reflecting pupil facet has a second reflectivity, the first coating area is different from the second coating area, and the first reflectivity is different from the second reflectivity. In combination or as an alternative, for at least some of the pupil facets which are designed as broadbands reflecting pupil facets, the broadband reflecting facets have a broadband reflective coating for the illumination light.

For increasing reflectivity a reflective optical element for the extreme ultraviolet wavelength range consists of at least two upper units, in which each upper unit (B1-B5) has a plurality of lower units, for example reflective optical elements in the form of mirror arrays. A method for producing the reflective optical element includes: determination of incidence angles and incidence angle bandwidths occurring during operation above the surface of each upper unit (B1-B5); and application of a reflective coating to each upper unit (B1-B5), adapted to the incidence angles and incidence angle bandwidths respectively determined above the surface of each upper unit. This is particularly suitable for producing reflective optical elements embodied as field facet mirrors, particularly in the form of microelectromechanical mirror arrays, for an EUV lithography device.

Extreme ultra-violet (EUV) lithography ruling engine specifically configured to print one-dimensional lines on a target workpiece includes source of EUV radiation; a pattern-source defining 1D pattern; an illumination unit (IU) configured to irradiate the pattern-source; and projection optics (PO) configured to optically image, with a reduction factor N>1, the 1D pattern on image surface that is optically-conjugate to the 1D pattern. Irradiation of the pattern-source can be on-axis or off-axis. While 1D pattern has first spatial frequency, its optical image has second spatial frequency that is at least twice the first spatial frequency. The pattern-source can be flat or curved. The IU may include a relay reflector. A PO's reflector may include multiple spatially-distinct reflecting elements aggregately forming such reflector. The engine is configured to not allow formation of optical image of any 2D pattern that has spatial resolution substantially equal to a pitch of the 1D pattern of the pattern-source.

System and method for monitoring of performance of a mirror array of a digital scanner with a use of light, illuminating the mirror array at grazing (off-axis) incidence, and an optical imaging system that includes a lateral shearing interferometer (operated in either static or a phase-shifting condition) during and without interrupting the process of exposure of the workpiece with the digital scanner, to either simply identify problematic pixels for further troubleshooting or measure the exact magnitude of the deformation of a mirror element of the mirror array.

One of gamma ray lithography systems includes a gamma ray generator and a wafer stage. The gamma ray generator is configured to generate a substantially uniform gamma ray. The gamma ray generator includes a plurality of gamma ray sources and a rotational carrier. The rotational carrier is configured to hold the gamma ray sources and rotate along a rotational axis. The wafer stage is disposed below the gamma ray generator and configured to secure a wafer.

A method of assembling a facet mirror of an optical system, in which facets of the facet mirror are imaged onto a field plane of the optical system, includes: a) determining positions of the facets of the facet mirror relative to interfaces of the facet mirror, with the aid of which the facet mirror is able to be connected to a support structure; b) calculating an actual position of an object field of the optical system arising for the facet mirror in the field plane; and c) arranging spacers between the interfaces and the support structure so that the object field in the field plane is brought from the calculated actual position to a target position.

A correction mask for an optical beam homogenizer includes a lens array. The correction mask is configured to provide a shaped initial beam profile. A subset of a plurality of optical paths between the incoming light beam and the illumination plane is at least partially blocked by the correction mask to provide a further homogenized beam profile having a further reduced light intensity variance with respect to an initial homogenized beam profile. The mask includes a plurality of submasks arranged according to a mask grid layout matching the lens grid layout of the lens array. Each one of the submasks is designed with a specific submask pattern to shape the respective subarea of the initial beam profile passing a specific one of the lenslets.

A correction mask for an optical beam homogenizer includes a lens array. The correction mask is configured to provide a shaped initial beam profile. A subset of a plurality of optical paths between the incoming light beam and the illumination plane is at least partially blocked by the correction mask to provide a further homogenized beam profile having a further reduced light intensity variance with respect to an initial homogenized beam profile. The mask includes a plurality of submasks arranged according to a mask grid layout matching the lens grid layout of the lens array. Each one of the submasks is designed with a specific submask pattern to shape the respective subarea of the initial beam profile passing a specific one of the lenslets.

The disclosure relates to a method for producing an illumination system for an EUV apparatus in and to an illumination system for an EUV apparatus.