Abstract: A lithographic apparatus includes a radiation system constructed to provide a beam of radiation from radiation emitted by a radiation source. The radiation system includes a contaminant trap configured to trap material emanating from the radiation source. The contaminant trap includes a contaminant engaging surface arranged in the path of the radiation beam that receives the material emanating from the radiation source during propagation of the radiation beam in the radiation system. The radiation system also includes a liquid tin cooling system constructed to cooling the contaminant trap with liquid tin. The apparatus includes an illumination system configured to condition the radiation beam, a support constructed to support a patterning device configured to impart the radiation beam with a pattern in its cross-section, a substrate table constructed to hold a substrate, and a projection system configured to project the patterned radiation beam onto a target portion of the substrate.

Abstract: A zone plate includes a plurality of consecutively arranged, adjacent, and alternating first and second regions. The first regions are arranged to be substantially transparent to a first predetermined wavelength of radiation and a second predetermined wavelength of radiation that is different from the first predetermined wavelength of radiation. The second regions are arranged to be substantially opaque, diffractive, or reflective to the first predetermined wavelength of radiation and substantially transparent to the second predetermined wavelength of radiation.

Abstract: A device constructed to generate radiation includes a liquid bath, and a pair of electrodes. At least a part of one of the electrodes is formed by a cable part moveable with respect to the liquid bath. The device also includes an actuator arranged to move the cable part from a liquid-adhering position to an ignition position, and an ignition source configured to trigger a discharge produced radiating plasma from the liquid adherent to the cable part, when the cable part is in the ignition position, by a discharge between the electrodes. The liquid-adhering position is a position for adhering a liquid from the bath to the part of the electrode.

Abstract: A radiation source includes a radiation emitter configured to emit radiation, a collector configured to collect the radiation, and a contamination trap configured to trap contamination emitted by the radiation source. The contamination trap includes a plurality of foils that extend substantially radially, a first magnet ring configured to lie outside of an outer conical trajectory of radiation that is collected by the collector, and a second magnet ring configured to lie within the trajectory of radiation that is collected by the collector. The magnet rings are configured to provide a magnetic field that includes a component that is parallel to the foils.

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 lithographic apparatus configured to project a patterned beam of radiation onto a target portion of a substrate is disclosed. The apparatus includes a first radiation dose detector and a second radiation dose detector, each detector comprising a secondary electron emission surface configured to receive a radiation flux and to emit secondary electrons due to the receipt of the radiation flux, the first radiation dose detector located upstream with respect to the second radiation dose detector viewed with respect to a direction of radiation transmission, and a meter, connected to each detector, to detect a current or voltage resulting from the secondary electron emission from the respective electron emission surface.

Abstract: An optical sensor apparatus for use in an extreme ultraviolet lithographic system is disclosed. The apparatus includes an optical sensor comprising a sensor surface and a removal mechanism configured to remove debris from the sensor surface. Accordingly, dose and/or contamination measurements may be carried out conveniently for the lithographic system.

Abstract: A method for the protection of an optical element of a lithographic apparatus is disclosed. A deposition gas comprising SnH4 is provided to the surface of the optical element to deposit a Sn cap layer on the surface of the optical element. In this way, a Sn cap layer is deliberately provided on the optical element, which may protect the optical element during lithographic processing from debris from a (Sn) plasma source. During or after lithographic processing, the (deteriorated) cap layer may be repaired by providing a hydrogen radical containing gas and/or a SnH4 containing gas. Additionally or alternatively, the (deteriorated) cap layer may be removed and a new cap layer provided by providing the deposition gas comprising SnH4.

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: A method of removing a deposition from an optical element of an apparatus. The method includes providing a hydrogen comprising gas in at least a part of the apparatus, providing nitrogen radicals in the part of the apparatus for generating hydrogen radicals from the hydrogen comprising gas, and contacting the optical element with at least part of the hydrogen radicals to removal the deposition.

Abstract: A debris prevention system is constructed and arranged to prevent debris that emanates from a radiation source from propagating with radiation from the radiation source into or within a lithographic apparatus. The debris prevention system includes an aperture that defines a maximum emission angle of the radiation coming from the radiation source, and a first debris barrier having a radiation transmittance. The first debris barrier includes a rotatable foil trap. The debris prevention system also includes a second debris barrier that has a radiation transmittance. The first debris barrier is configured to cover a part of the emission angle and the second debris barrier is configured to cover another part of the emission angle.

Abstract: A lithographic apparatus includes a radiation system constructed to provide a beam of radiation from radiation emitted by a radiation source. The radiation system includes a contaminant trap configured to trap material emanating from the radiation source. The contaminant trap includes a contaminant engaging surface arranged in the path of the radiation beam that receives the material emanating from the radiation source during propagation of the radiation beam in the radiation system. The radiation system also includes a liquid tin cooling system constructed to cooling the contaminant trap with liquid tin. The apparatus includes an illumination system configured to condition the radiation beam, a support constructed to support a patterning device configured to impart the radiation beam with a pattern in its cross-section, a substrate table constructed to hold a substrate, and a projection system configured to project the patterned radiation beam onto a target portion of the substrate.

Abstract: An assembly including a radiation reflector and a contaminant barrier is disclosed. The contaminant barrier is arranged to receive radiation from a radiation source and to reflect that radiation towards the radiation reflector, and the radiation reflector is arranged to reflect the radiation, received from the contaminant barrier, back towards the contaminant barrier.

Abstract: A device constructed to generate radiation includes a liquid bath, and a pair of electrodes. At least a part of one of the electrodes is formed by a cable part moveable with respect to the liquid bath. The device also includes an actuator arranged to move the cable part from a liquid-adhering position to an ignition position, and an ignition source configured to trigger a discharge produced radiating plasma from the liquid adherent to the cable part, when the cable part is in the ignition position, by a discharge between the electrodes. The liquid-adhering position is a position for adhering a liquid from the bath to the part of the electrode.

Abstract: A device is arranged to measure a quantity relating to radiation. The device includes a sensor configured to measure the quantity, a screen arranged to protect the sensor from incoming particles emitted from a source configured to emit extreme ultraviolet radiation, and a mirror configured to redirect extreme ultraviolet radiation emitted by the source, past the screen, to the sensor.

Abstract: A debris mitigation system for trapping contaminant material coming from a debris-generating radiation source. The system includes a contamination barrier constructed and arranged to rotate about an axis, and a magnet structure constructed and arranged to provide a magnetic field for deflecting charged debris from the radiation source. The magnet structure is constructed and arranged to provide a magnetic field through the contamination barrier. The magnetic field, when passing through the contamination barrier, is oriented along planes generally coinciding with the axis of rotation of the contamination barrier.

Abstract: A debris mitigation system for trapping debris coming from a tin debris-generating radiation source is provided. The debris mitigating system includes a debris barrier comprising a plurality of foils, and a cleaning system constructed and arranged to clean the foils. The cleaning system includes a supply unit to provide a liquid alloy to the foils to dissolve and flush trapped debris from the foils. The alloy includes gallium, indium, tin, or any combination thereof.

Abstract: A patterning device for a photolithographic apparatus is used to form a patterned radiation beam, by imparting a cross-sectional pattern to the radiation beam during reflection from the patterning device. The patterning device comprises a layer of phase-change material that is capable of locally undergoing an induced structural phase change into respective ones of a plurality of stable and/or metastable states. Furthermore, the patterning device comprises a radiation reflective structure with periodically arranged layers adjacent to the layer of phase-change material. The radiation reflective structures do not partake in the phase changes. By locally changing the phase of the phase-change material, the reflectivity of the whole structure is modified, for example due to thickness changes in the layer of phase-change material that lead to destructive interference of different components of the reflected light or due to changes in surface roughness of the radiation reflective structure.

Abstract: A radiation system for generating a beam of radiation that defines an optical axis is provided. The radiation system includes a plasma produced discharge source for generating EUV radiation. The discharge source includes a pair of electrodes constructed and arranged to be provided with a voltage difference, and a system for producing a plasma between the pair of electrodes so as to provide a discharge in the plasma between the electrodes. The radiation system also includes a debris catching shield for catching debris from the electrodes. The debris catching shield is constructed and arranged to shield the electrodes from a line of sight provided in a predetermined spherical angle relative the optical axis, and to provide an aperture to a central area between the electrodes in the line of sight.

Abstract: An optical sensor apparatus for use in an extreme ultraviolet lithographic system is disclosed. The apparatus includes an optical sensor comprising a sensor surface and a removal mechanism configured to remove debris from the sensor surface. Accordingly, dose and/or contamination measurements may be carried out conveniently for the lithographic system.