Abstract: A map of the surface of a substrate is generated at a measurement station. The substrate is then moved to where a space between a projection lens and the substrate is filled with a liquid. The substrate is then aligned using, for example, a transmission image sensor and, using the previous mapping, the substrate can be accurately exposed. Thus the mapping does not take place in a liquid environment.

Abstract: A lithographic apparatus configured to project a patterned radiation beam onto a target portion of a substrate held on a substrate holder in an indent on a substrate table, the apparatus includes a liquid supply system configured to at least partly fill a space between a projection system and the substrate with liquid; a barrier structure configured to substantially contain the liquid within the space; and a heat pipe supplied, in use, with a temperature conditioned fluid and configured to thermally condition the substrate and/or the substrate holder at locations where localized cooling is likely to occur.

Abstract: A lithographic apparatus is described having a liquid supply system configured to at least partly fill a space between a projection system of the lithographic apparatus and a substrate with liquid, a barrier member arranged to substantially contain the liquid within the space, and a heater.

Abstract: A lithographic apparatus is described having a liquid supply system configured to at least partly fill a space between a projection system of the lithographic apparatus and a substrate with liquid, a barrier member arranged to substantially contain the liquid within the space, and a heater.

Abstract: A radiation collector comprising a first collector segment comprising a plurality of grazing incidence reflector shells configured to direct radiation to converge in a first location at a distance from the radiation collector, a second collector segment comprising a plurality of grazing incidence reflector shells configured to direct radiation to converge in a second location at said distance from the radiation collector, wherein the first location and the second location are separated from one another.

Abstract: Lithography apparatus and device manufacturing methods are disclosed in which means are provided for reducing the extent to which vibrations propagate between a first element of a projection system and a second element of a projection system. Approaches disclosed include the use of plural resilient members in series as part of a vibration isolation system, plural isolation frames for separately supporting first and second projection system frames, and modified connection positions for the interaction between the first and second projection system frames and the isolation frame(s).

Abstract: An immersion lithographic projection apparatus is disclosed in which liquid is provided between a projection system of the apparatus and a substrate. The use of both liquidphobic and liquidphilic layers on various elements of the apparatus is provided to help prevent formation of bubbles in the liquid and to help reduce residue on the elements after being in contact with the liquid.

Abstract: In a lithographic projection apparatus, a structure surrounds a space between the projection system and a substrate table of the lithographic projection apparatus. A gas seal is formed between said structure and the surface of said substrate to contain liquid in the space.

Abstract: A system is disclosed for reducing overlay errors by controlling gas flow around a patterning device of a lithographic apparatus. The lithographic apparatus includes an illumination system configured to condition a radiation beam. The lithographic apparatus further includes a movable stage comprising a support structure that may be configured to support a patterning device. The patterning device may be configured to impart the radiation beam with a pattern in its cross-section to form a patterned radiation beam. In addition, the lithographic apparatus comprises a plate (410) positioned between the movable stage (401) and the projection system (208). The plate includes an opening (411) that comprises a first sidewall (411a) and a second sidewall (411b). The plate may be configured to provide a gas flow pattern (424) in a region between the movable stage and the projection system that is substantially perpendicular to an optical axis of the illumination system.

Abstract: A lithographic apparatus includes a radiation source configured to produce extreme ultraviolet radiation, the radiation source including a chamber in which a plasma is generated; a collector mirror configured to reflect radiation emitted by the plasma; and a debris mitigation system including a gas supply system configured to supply a first gas flow toward the plasma, the first gas flow being selected to thermalize debris generated by the plasma, and a plurality of gas manifolds arranged at a location proximate the collector mirror, the gas manifolds configured to supply a second gas flow in the chamber, the second gas flow being directed toward the plasma to prevent thermalized debris from depositing on the collector mirror.

Abstract: A lithographic projection apparatus includes a support structure configured to hold a patterning device, the patterning device configured to pattern a beam of radiation according to a desired pattern; a substrate table configured to hold a substrate; a projection system configured to project the patterned beam onto a target portion of the substrate; a liquid supply system configured to provide liquid to a space between the projection system and the substrate; and a shutter configured to isolate the space from the substrate or a space to be occupied by a substrate.

Abstract: A map of the surface of a substrate is generated at a measurement station. The substrate is then moved to where a space between a projection lens and the substrate is filled with a liquid. The substrate is then aligned using, for example, a transmission image sensor and, using the previous mapping, the substrate can be accurately exposed. Thus the mapping does not take place in a liquid environment.

Abstract: A lithographic apparatus is described having a liquid supply system configured to at least partly fill a space between a projection system of the lithographic apparatus and a substrate with liquid, a barrier member arranged to substantially contain the liquid within the space, and a heater.

Abstract: A radiation source having a nozzle configured to direct a stream of fuel droplets along a trajectory towards a plasma formation location, a laser configured to direct laser radiation at the fuel droplets at the plasma formation location to generate, in use, a radiation generating plasma. The nozzle has an internal surface that is configured to prevent contamination present in fuel used to form the fuel droplets from being deposited on that internal surface.

Abstract: Disclosed is a system configured to project a beam of radiation onto a target portion of a substrate within a lithographic apparatus. The system comprises a mirror (510) having an actuator (500) for positioning the mirror and/or configuring the shape of the mirror, the actuator also providing active damping to the mirror, and a controller (515a, 515b) for generating actuator control signals for control of said actuator(s). A first coordinate system is used for control of said actuator(s) when positioning said mirror and/or configuring the shape of said mirror and a second coordinate system is used for control of said actuator(s) when providing active damping to said mirror.

Abstract: Liquid is supplied to a space between the projection system of a lithographic apparatus and a substrate. A flow of gas towards a vacuum inlet prevents the humid gas from escaping to other parts of the lithographic apparatus. This may help to protect intricate parts of the lithographic apparatus from being damaged by the presence of humid gas.

Abstract: A radiation source generates extreme ultraviolet radiation for a lithographic apparatus as a chamber that is provided with a low pressure hydrogen environment. A trace amount of a protective compound, e.g., H2O, H2O2, O2, NH3 or NOx, is provided to the chamber to assist in maintaining a protective oxide film on metal, e.g., titanium, components in the chamber.

Abstract: A projection system (PS) is provided which includes, in an embodiment, two frames. The optical elements of the projection system are mounted on a first frame (200). The position of the optical elements is measured relative to a second frame (300) using a first measurement system (910). A second measurement system (920) is used to measure a parameter associated with a deformation of the second frame. The measurement made by the second measurement system can be used to compensate for any errors in the position of the optical elements as measured by the first measurement system resulting from deformations of the second frame. Typically, deformations of the frames are due to resonant oscillation and thermal expansion. Having two frames enables the optical elements of the projection system to be positioned with a high degree of accuracy.

Abstract: A method of generating radiation for a lithography apparatus. The method comprises providing a continuously renewing fuel target (50) at a plasma formation location (12) and directing a continuous-wave excitation beam (6) at the plasma formation location such that fuel within the continuously renewing fuel target is excited by the continuous-wave excitation beam to generate a radiation generating plasma.

Abstract: An exposure apparatus including a movable table, a member, movably separate from the table and located on a top surface of the table, to provide a surface substantially co-planar with a top surface of an object in or on the table, a projection system configured to project a radiation beam onto a radiation-sensitive target portion of a substrate, and a liquid supply system configured to provide a liquid to a space between the projection system and the object.