Abstract: The invention provides a method for creating in a display space an ambience lighting effect, wherein the display space comprises a screen configured to display moving images and a display space light source configured to provide the ambience lighting effect, wherein the moving images are representative of a stage performance in a performance space, the method comprising (a) deriving ambience lighting effect input data from one or more of (i) a light related cue provided by a cue manager, (ii) lighting effects accompanying the stage performance, and (iii) an analysis of a video shot by a video camera configured to monitor at least a part of an audience present in the performance space; and (b) displaying the moving images on the screen in the display space, while creating with the display space light source said ambience lighting effect at least based on the ambience lighting effect input data.

Abstract: A radiation source is configured to generate extreme ultraviolet radiation. The radiation source includes a plasma formation site located at a position in which a fuel is contacted by a beam of radiation to form a plasma, a collector constructed and arranged to collect extreme ultraviolet radiation formed at the plasma formation site and form an extreme ultraviolet radiation beam, and a contamination barrier. The contamination barrier includes a plurality of foils at least partially located between the plasma formation site and the collector, and a rotatable base operatively connected to the plurality of foils. The rotatable base is configured to allow the beam of radiation to pass through the contamination barrier to the plasma formation site.

Abstract: A method of cleaning an imprint template is disclosed. The method includes exposing the imprint template to a reductive fluid.

Abstract: A debris prevention system is constructed and arranged to prevent debris emanating from a radiation source from propagating with radiation from the radiation source into or within a lithographic apparatus. The debris prevention system includes a first foil trap that is rotatable around an axis of rotation, and a second foil trap that at least partly encloses the first foil trap. The second foil trap includes a plurality of foils optically open respective to a central location for placement of a radiation source and optically closed respective to directions perpendicular to the axis of rotation.

Abstract: An EUV mask includes, on top of a multi-layer mirror, a spectral purity enhancement layer, for application in an EUV lithographic apparatus. On top of the spectral purity enhancement layer, a patterned absorber layer is provided. The spectral purity enhancement layer includes a first spectral purity enhancement layer, but between the multi-layer mirror and first spectral purity enhancement layer there may be an intermediate layer or a second spectral purity enhancement layer and intermediate layer. The patterned absorber layer may also itself function as an anti-reflection (AR) coating. The AR effect of this absorber layer is a function of the aperture sizes in the pattern. The spectral purity of a mask may be enhanced, such that DUV radiation is diminished relatively stronger than EUV radiation.

Abstract: A radiation system for generating a beam of radiation is disclosed. The radiation system includes a pulsed EUV source for generating EUV radiation, and a spectral filter mounted in front of the EUV source for selectively passing a spectral range of a beam of EUV radiation from the EUV source. The spectral filter is mounted on a movable mount configured to be moved in synchronicity with the pulsed EUV source to prevent debris traveling from the EUV source from impacting the spectral filter. Accordingly, the spectral filter is kept substantially free from contamination by the debris.

Abstract: An EUV lithographic apparatus includes an EUV radiation source, an optical element and a cleaning device. The cleaning device includes a hydrogen radical source and a flow tube in communication with the hydrogen radical source. The cleaning device is configured to provide a flow of hydrogen radicals and the flow tube is arranged to provide a hydrogen radical flow at a predetermined position within the lithographic apparatus, for example for cleaning a collector mirror.

Abstract: The invention relates to a radiation system for generating a beam of radiation. The radiation system includes an extreme ultraviolet source constructed and arranged to generate extreme ultraviolet radiation, a contamination barrier constructed and arranged to trap contamination from the radiation source, and a temperature sensor constructed and arranged to sense a temperature of the contamination barrier.

Abstract: A multi-layer mirror includes on top of the multi-layer mirror a spectral purity enhancement layer, for example for application in an EUV lithographic apparatus. This spectral purity enhancement layer includes a first spectral purity enhancement layer, but between the multi-layer mirror and first spectral purity enhancement layer there may optionally be an intermediate layer or a second spectral purity enhancement layer and intermediate layer. Hence, multi-layer mirrors with the following configurations are possible: multi-layer mirror/first spectral purity enhancement layer; multi-layer mirror/intermediate layer/first spectral purity enhancement layer; and multi-layer mirror/second spectral purity enhancement layer/intermediate layer/first spectral purity enhancement layer. The spectral purity of normal incidence radiation may be enhanced, such that DUV radiation is diminished relatively stronger than EUV radiation.

Abstract: A multi-layer mirror includes on top of the multi-layer mirror a spectral purity enhancement layer, for example for application in an EUV lithographic apparatus. This spectral purity enhancement layer includes a first spectral purity enhancement layer, but between the multi-layer mirror and first spectral purity enhancement layer there may optionally be an intermediate layer or a second spectral purity enhancement layer and intermediate layer. Hence, multi-layer mirrors with the following configurations are possible: multi-layer mirror/first spectral purity enhancement layer; multi-layer mirror/intermediate layer/first spectral purity enhancement layer; and multi-layer mirror/second spectral purity enhancement layer/intermediate layer/first spectral purity enhancement layer. The spectral purity of normal incidence radiation may be enhanced, such that DUV radiation is diminished relatively stronger than EUV radiation.

Abstract: A spectral purity filter includes an aperture, the aperture having a diameter, wherein the spectral purity filter is configured to enhance the spectral purity of a radiation beam by reflecting radiation of a first wavelength and allowing at least a portion of radiation of a second wavelength to transmit through the aperture, the first wavelength being larger than the second wavelength. The spectral purity filter may be used to improve the spectral purity of an Extreme Ultra-Violet (EUV) radiation beam.

Abstract: A debris trapping system for trapping debris particles released with the generation of radiation by a radiation source in a lithographic apparatus includes first and second sets of channels. Each channel of the first set enables radiation from a radiating source to propagate therethrough and has an inner wall for catching debris particles. The second set of channels is situated downstream of the first set with respect to a propagation direction of the radiation. Each channel of the second set enables radiation from the radiating source to also propagate therethrough and has an inner wall for catching debris particles. A gas supply and a gas exhaust are configured to provide between the first set and the second set of channels a gas flow having a net flow direction substantially across the propagation direction of the radiation from a radiating source.

Abstract: A lithographic apparatus includes a source for generating radiation bursts with a predetermined frequency, an illumination system for conditioning the radiation, a patterning device for patterning the radiation, and a projection system for projecting the patterned radiation onto a substrate. The illumination system includes a debris mitigating system for mitigating debris particles released with the generation of the radiation. The debris mitigating system is arranged to apply on the basis of the predetermined frequency a dynamically applicable condition to which the debris particles are exposed.

Abstract: A method for the removal of a deposition on an optical element of an apparatus including the optical element includes providing an H2 containing gas in at least part of the apparatus includes producing hydrogen radicals from H2 from the H2 containing gas; and bringing the optical element with deposition into contact with at least part of the hydrogen radicals and removing at least part of the deposition. Further, a method for the protection of an optical element of an apparatus including the optical element includes providing a cap layer to the optical element by a deposition process; and during or after use of the apparatus, removing at least part of the cap layer from the optical element in a removal process as described above. The methods can be applied in a lithographic apparatus.