Abstract: A radiation source includes a chamber, a supply constructed and arranged to supply a substance to the chamber at a location that allows the substance to pass through an interaction point within the chamber, a laser constructed and arranged to provide a laser beam to the interaction point so that a radiation emitting plasma is produced when the laser beam interacts with the substance at the interaction point, and a conduit constructed and arranged to deliver a buffer gas into the chamber. The conduit has an outlet located adjacent to the interaction point.

Abstract: A lithographic apparatus is disclosed. The apparatus includes a source for supplying hydrogen radicals, a guide for use in conjunction with the source, for directing hydrogen radicals to an application surface to be targeted by the hydrogen radicals. The guide is provided with a coating having a hydrogen radical recombination constant of less than 0.2. In this way, the radicals can be transported with reduced losses and are able to better interact with remaining contaminants on application surfaces, such as mirror surfaces.

Abstract: A radiation source for generation of extreme ultraviolet radiation or use in high resolution lithography includes a plasma formation site where fuel is contacted by a radiation beam to form a plasma generating EUV radiation. A mirrored collector collects and reflects the EUV radiation generated at a first focus towards a second focus. A contamination barrier is positioned such the periphery of the contamination barrier does not occlude more than 50% of the solid angle subtended by the mirror at the second focus, such that EUV radiation reflected by the collector mirror is not excessively attenuated by passing through the contamination barrier. The contamination barrier serves to trap fuel material such as ions, atoms, molecules or nanodroplets from the plasma to prevent their deposition onto the collector mirror where they reduce the mirror's effective lifetime.

Abstract: A multi-layer mirror includes a multi-layer stack. The multi-layer stack includes a plurality of alternating layers with a multi-layer stack top layer and a spectral filter top layer arranged on the multi-layer stack. The spectral filter top layer includes a first spectral purity enhancement layer that includes a first material m1 and has a first layer thickness d1, an intermediate layer that includes a second material m2 and has a second layer thickness d2. The intermediate layer is arranged on the multi-layer stack top layer. The first material is selected from SiN, Si3N4, SiO2, ZnS, Te, diamond, CsI, Se, SiC, amorphous carbon, MgF2, CaF2, TiO2, Ge, PbF2, ZrO2, BaTiO3, LiF or NaF. The second material includes a material different from the first material, and d1+d2 has a thickness between 1.5 and 40 nm.

Abstract: Embodiments of the invention relate to a system for contactless cleaning of an object surface, a lithographic apparatus including the system, and a method of manufacturing a device. The system may include a He plasma source contained in a chamber and a control unit constructed to modify plasma parameters in use, such as the electron energy distribution of the plasma for causing an increase in formation of He metastables without modifying operational parameters of the plasma source. The control unit may include an electrical biasing unit constructed to apply a positive bias voltage to the object, for attracting free electrons from the plasma. The system may include a supplementary gas source, which may be either pre-mixed with He or be supplied from a further gas source. The supplementary gas may be selected based on a pre-knowledge on a type of particles to be expected on the surface of the object.

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 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: A lithographic apparatus and device manufacturing method makes use of a liquid confined in a reservoir between the projection system and the substrate. Bubbles forming in the liquid from dissolved atmospheric gases or from out-gassing from apparatus elements exposed to the liquid are detected and/or removed so that they do not interfere with exposure and lead to printing defects on the substrate. Detection may be carried out by measuring the frequency dependence of ultrasonic attenuation in the liquid and bubble removal may be implemented by degassing and pressurizing the liquid, isolating the liquid from the atmosphere, using liquids of low surface tension, providing a continuous flow of liquid through the imaging field, and/or phase shifting ultrasonic standing-wave node patterns.

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 source configured to generate EUV radiation includes a fuel droplet generator configured to deliver a droplet of fuel to an interaction point, optics configured to deliver fuel vaporizing and exciting radiation to the interaction point to generate a plasma, and a collector arranged to collect EUV radiation emitted by the plasma. The optics are arranged such that in use the fuel vaporizing and exciting radiation is incident upon more than one side of the fuel droplet at the interaction point.

Abstract: A transmissive fly's eye integrator is disclosed that includes a first array of lenses and a second array of lenses. The first array of lenses and second array of lenses together form a fly's eye integrator, and the first array of lenses and second array of lenses comprise lenses which have a diameter selected from the range of 5 ?m-50 ?m, and a radius of curvature selected from the range of 25 ?m-2500 ?m.

Abstract: A multi-layer mirror includes a multi-layer stack. The multi-layer stack includes a plurality of alternating layers with a multi-layer stack top layer and a spectral filter top layer arranged on the multi-layer stack. The spectral filter top layer includes a first spectral purity enhancement layer that includes a first material m1 and has a first layer thickness d1, an intermediate layer that includes a second material m2 and has a second layer thickness d2. The intermediate layer is arranged on the multi-layer stack top layer. The first material is selected from SiN, Si3N4, SiO2, ZnS, Te, diamond, CsI, Se, SiC, amorphous carbon, MgF2, CaF2, TiO2, Ge, PbF2, ZrO2, BaTiO3, LiF or NaF. The second material includes a material different from the first material, and d1+d2 has a thickness between 1.5 and 40 nm.

Abstract: The invention relates to a radiation system for generating electromagnetic radiation. The radiation system includes a pair of electrodes constructed and arranged to generate plasma of a first substance and a pinch in the plasma. The radiation system also includes a plasma recombination surface that is arranged proximate to the pinch, and is configured to neutralize a plurality of plasma particles.

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: A radiation source is configured to generate extreme ultraviolet radiation. The radiation source includes a fuel supply configured to supply a fuel to a plasma formation site; a laser configured to emit a beam of radiation to the plasma formation site so that a plasma that emits extreme ultraviolet radiation is generated when the beam of radiation impacts the fuel; a fuel particulate interceptor constructed and arranged to shield at least part of the radiation source from fuel particulates that are emitted by the plasma, the fuel particulate interceptor comprising a first portion and a second portion, the second portion being positioned closer to the plasma formation site than the first portion, and the first portion being rotatable; and a fuel particulate remover constructed and arranged to remove fuel particulates from a surface of the fuel particulate interceptor and to direct the fuel particulates towards a collection location.

Abstract: A lithographic apparatus is configured to project a pattern from a patterning device onto a substrate. The apparatus includes a gas purged sealing aperture extending between at least two different zones of the apparatus, and a gas supplier configured to supply the sealing aperture one or more gases selected from a group including hydrogen, deuterium, heavy hydrogen, deuterated hydrogen, and a mixture of argon and hydrogen.

Abstract: A lithographic apparatus and device manufacturing method makes use of a liquid confined in a reservoir between the projection system and the substrate. Bubbles forming in the liquid from dissolved atmospheric gases or from out-gassing from apparatus elements exposed to the liquid are detected and/or removed so that they do not interfere with exposure and lead to printing defects on the substrate. Detection may be carried out by measuring the frequency dependence of ultrasonic attenuation in the liquid and bubble removal may be implemented by degassing and pressurizing the liquid, isolating the liquid from the atmosphere, using liquids of low surface tension, providing a continuous flow of liquid through the imaging field, and/or phase shifting ultrasonic standing-wave node patterns.

Abstract: A radiation source is configured to generate extreme ultraviolet radiation. The radiation source includes a droplet generator constructed and arranged to generate fuel droplets, a heater constructed and arranged to heat the fuel droplets following generation of the fuel droplets by the droplet generator, and reduce the mass of fuel present in the fuel droplets and/or reduce the density of the fuel droplets, and a radiation emitter constructed and arranged to direct radiation onto the fuel droplets that have been heated by the heater to generate the extreme ultraviolet radiation.

Abstract: A lithographic apparatus includes a radiation source configured to produce extreme ultraviolet radiation. The source includes a chamber in which a plasma is generated, and a mirror configured to reflect radiation emitted by the plasma. The mirror includes a multi-layer structure that includes alternating Mo/Si layers. A boundary Mo layer or a boundary Si layer or a boundary diffusion barrier layer of the alternating layers forms a top layer of the mirror, the top layer facing inwardly with respect to the chamber. A hydrogen radical generator is configured to generate hydrogen radicals in the chamber. The radicals are configured to remove debris generated by the plasma from the mirror. A support is constructed and arranged to support a patterning device configured to pattern the radiation to form a patterned beam of radiation. A projection system is constructed and arranged to project the patterned beam of radiation onto a substrate.

Abstract: A radiation source is configured to generate extreme ultraviolet radiation. The radiation source includes a laser constructed and arranged to generate a beam of radiation directed to a plasma generation site where a plasma is generated when the beam of radiation interacts with a fuel, an optical component having a surface that is arranged and positioned to be hit by a droplet of fuel, and a temperature conditioner constructed and arranged to elevate the temperature of the surface.