Abstract: An apparatus for forming a beam of electromagnetic radiation. The apparatus includes a plasma radiation source, a foil trap provided with a plurality of thin foils that extend substantially parallel to the direction of radiation from the plasma source, and a grid disposed between the plasma radiation source and the foil trap. A space is located between the grid and the foil trap. An electrical potential application circuit is constructed and arranged to apply an electrical potential to the grid so that the grid repels electrons emitted by the plasma radiation source and creates a positive space charge between the grid and the foil trap to deflect ions emitted by the plasma radiation source to the foil trap. A distance between the grid and the foil trap is at least equal to one-half of a radius of the foil trap.

Abstract: A multilayer mirror is configured to reflect extreme ultraviolet (EUV) radiation while absorbing a second radiation having a wavelength substantially-longer than that of the EUV radiation. The mirror includes a plurality of layer pairs stacked on a substrate. Each layer pair comprises a first layer that includes a first material, and a second layer that includes a second material. The first layer is modified to reduce its contribution to reflection of the second radiation, compared with a simple layer of the same metal having the same thickness. Modifications can include doping with a third material in or around the metal layer to reduce its electric conductivity by chemical bonding or electron trapping, and/or splitting the metal layer into sub-layers with insulating layers. The number of layers in the stack is larger than known multilayer mirrors and may be tuned to achieve a minimum in IR reflection.

Abstract: A collector assembly with a radiation collector, a cover plate and a support member connecting the radiation collector to the cover plate are provided. The cover plate is designed to cover an opening in a collector chamber. The collector chamber opening may be large enough to pass the radiation collector and the support member. The removed radiation collector can be cleaned with different cleaning procedures, which may be performed in a cleaning device. Such cleaning device may for example consist of the following: a circumferential hull designed to provide an enclosure volume for circumferentially enclosing at least the radiation collector; an inlet configured to provide at least one of a cleaning gas and a cleaning liquid to the enclosure volume to clean at least said radiation collector; and an outlet configured to remove said at least one of said cleaning gas and said cleaning liquid from the enclosure volume.

Abstract: A collector assembly with a radiation collector, a cover plate and a support member connecting the radiation collector to the cover plate are provided. The cover plate is designed to cover an opening in a collector chamber. The collector chamber opening may be large enough to pass the radiation collector and the support member. The removed radiation collector can be cleaned with different cleaning procedures, which may be performed in a cleaning device. Such cleaning device may for example consist of the following: a circumferential hull designed to provide an enclosure volume for circumferentially enclosing at least the radiation collector; an inlet configured to provide at least one of a cleaning gas and a cleaning liquid to the enclosure volume to clean at least said radiation collector; and an outlet configured to remove said at least one of said cleaning gas and said cleaning liquid from the enclosure volume.

Abstract: A radiation system is configured to generate a radiation beam. The radiation system includes a radiation source configured to generate a plasma that emits radiation and debris, and a radiation collector configured to direct collected radiation to a radiation beam emission aperture. A magnetic field generator is configured to generate a magnetic field with a gradient in magnetic field strength to direct the plasma away from the radiation collector.

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 will be contacted by a beam of radiation to form a plasma, an outlet configured to allow gas to exit the radiation source, and a contamination trap at least partially located inside the outlet. The contamination trap is configured to trap debris particles that are generated with the formation of the plasma.

Abstract: A lithographic apparatus includes an illumination system configured to condition a beam of radiation, and a support structure configured to support a patterning device. The patterning device is configured to impart a pattern to the beam of radiation. The apparatus includes a patterning device cleaning system configured to provide an electrostatic force to contaminant particles that are on the patterning device and that are electrically charged by the beam of radiation, in order to remove the contaminant particles from the patterning device.

Abstract: A radiation source is constructed and arranged to produce extreme ultraviolet radiation. The radiation source includes a chamber, a first electrode at least partially contained in the chamber, a second electrode at least partially contained in the chamber, and a supply constructed and arranged to provide a discharge gas to the chamber. The first electrode and the second electrode are configured to create a discharge in the discharge gas to form a plasma so as to generate the extreme ultraviolet radiation. The source also includes a gas supply constructed and arranged to provide a gas at a partial pressure between about 1 Pa and about 10 Pa at a location near the discharge. The gas is selected from the group consisting of hydrogen, helium, and a mixture of hydrogen and helium.

Abstract: An apparatus for forming a beam of electromagnetic radiation. The apparatus includes a plasma radiation source, a foil trap provided with a plurality of thin foils that extend substantially parallel to the direction of radiation from the plasma source, and a grid disposed between the plasma radiation source and the foil trap. A space is located between the grid and the foil trap. An electrical potential application circuit is constructed and arranged to apply an electrical potential to the grid so that the grid repels electrons emitted by the plasma radiation source and creates a positive space charge between the grid and the foil trap to deflect ions emitted by the plasma radiation source to the foil trap. A distance between the grid and the foil trap is at least equal to one-half of a radius of the foil trap.

Abstract: A source configured to generate radiation for a lithographic apparatus is disclosed. The source includes an anode, and a cathode. The cathode and the anode are configured to create a discharge in a fuel in a discharge space between the anode and the cathode so as to generate a plasma, the cathode and the anode positioned relative to each other so that, in use, current lines extending between the anode and the cathode are substantially curved so as to create a force that substantially radially compresses the plasma only in a region proximate an upper surface of the cathode or of the anode.

Abstract: A collector assembly with a radiation collector, a cover plate and a support member connecting the radiation collector to the cover plate are provided. The cover plate is designed to cover an opening in a collector chamber. The collector chamber opening may be large enough to pass the radiation collector and the support member. The removed radiation collector can be cleaned with different cleaning procedures, which may be performed in a cleaning device. Such cleaning device may for example consist of the following: a circumferential hull designed to provide an enclosure volume for circumferentially enclosing at least the radiation collector; an inlet configured to provide at least one of a cleaning gas and a cleaning liquid to the enclosure volume to clean at least said radiation collector; and an outlet configured to remove said at least one of said cleaning gas and said cleaning liquid from the enclosure volume.

Abstract: An assembly is provided for blocking a beam of radiation. The assembly has a pipe arranged to transmit at least part of the beam of radiation. The pipe has an inner surface provided with an ablation material and encloses a volume. The assembly further has an ablation generation device. The ablation generation device is arranged to ablate at least a portion of the ablation material upon reception of a blocking signal. The assembly has a control unit, which is arranged to control the ablation generation device.

Abstract: A collector assembly with a radiation collector, a cover plate and a support member connecting the radiation collector to the cover plate are provided. The cover plate is designed to cover an opening in a collector chamber. The collector chamber opening may be large enough to pass the radiation collector and the support member. The removed radiation collector can be cleaned with different cleaning procedures, which may be performed in a cleaning device. Such cleaning device may for example consist of the following: a circumferential hull designed to provide an enclosure volume for circumferentially enclosing at least the radiation collector; an inlet configured to provide at least one of a cleaning gas and a cleaning liquid to the enclosure volume to clean at least said radiation collector; and an outlet configured to remove said at least one of said cleaning gas and said cleaning liquid from the enclosure volume.

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 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 discharge produced plasma radiation source includes a laser beam pulse generator configured to provide a laser beam pulse to trigger a pinch in a plasma of the discharge produced plasma radiation source. The laser beam pulse generator is arranged to provide a laser beam pulse having an energy greater than an optimum laser beam pulse energy that corresponds to a maximum output of a given wavelength of radiation for a given discharge energy.

Abstract: An apparatus for producing radiation by an electrically operated discharge has a first electrode, a second electrode. and a capacitor bank. The electrodes are configured at a distance from each other which allows plasma ignition. The capacitor bank is electrically connected at a first terminal to the first electrode and at a second terminal to the second electrode, and configured to store a discharge energy. The electrodes and the capacitor bank form an electric circuit. At least the first electrode is formed by an electrically conducting fluid supplied via a first feeding line. The apparatus further has a charger and a first high inductance unit. The charger is connected to at least one of the terminals. The first high inductance unit is provided upstream the first terminal in the first feeding line for electrically decoupling the electric circuit.

Abstract: A radiation source comprises an anode and a cathode that are configured and arranged to create a discharge in a gas or vapor in a space between anode and cathode and to form a plasma pinch so as to generate electromagnetic radiation. The gas or vapor may comprise xenon, indium, lithium and/or tin. The radiation source may comprise a plurality of discharge elements, each of which is only used for short intervals, after which another discharge element is selected. The radiation source may also comprise a triggering device, which device can facilitate improving the exact timing of the pinch formation and thus the pulse of EUV radiation. The radiation source may also be constructed to have a low inductance, and operated in a self-triggering regime.

Abstract: A radiation source is disclosed that includes an anode and a cathode that are configured and arranged to create a discharge in a substance in a discharge space between the anode and the cathode and to form a plasma so as to generate electromagnetic radiation, the anode and the cathode being rotatably mounted around an axis of rotation, the cathode being arranged to hold a liquid metal. The radiation source further includes an activation source arranged to direct an energy beam onto the liquid metal so as to vaporize part of the liquid metal and a liquid metal provider arranged to supply additional liquid metal so as to compensate for the vaporized part of the liquid metal.

Abstract: A source configured to generate radiation for a lithographic apparatus is disclosed. The source includes an anode, and a cathode. The cathode and the anode are configured to create a discharge in a fuel in a discharge space between the anode and the cathode so as to generate a plasma, the cathode and the anode positioned relative to each other so that, in use, current lines extending between the anode and the cathode are substantially curved so as to create a force that substantially radially compresses the plasma only in a region proximate an upper surface of the cathode or of the anode.