Abstract: A method and apparatus for controlling the seed laser in a laser produced plasma (LPP) extreme ultraviolet (EUV) light system are disclosed. In one embodiment, a seed laser generates both pre-pulses and main pulses which are amplified and irradiate a target material. The widths of the main pulses are adjusted, for example by the use of an EOM or other optical switch, without adjusting the widths of the pre-pulses, to keep the EUV output energy at a desired level. Only if the main pulse widths are longer or shorter than a desired range is the duty cycle of the laser amplifier adjusted, to keep the main pulse widths in the desired range. Adjusting the main pulse widths in this way before adjusting the pump RF duty cycle allows for less adjustment of the duty cycle, thus causing less adjustment to the pre-pulses.

Abstract: An extreme-ultraviolet (EUV) light source is described herein comprising an optic; a primary EUV light radiator generating an EUV light emitting plasma and producing a deposit on said optic; and a cleaning system comprising a gas and a secondary light radiator, the secondary light radiator generating a laser produced plasma and producing a cleaning species with the gas.

Abstract: A system for an extreme ultraviolet light source includes one or more optical elements positioned to receive a reflected amplified light beam and to direct the reflected amplified light beam into first, second, and third channels, the reflected amplified light beam including a reflection of at least a portion of an irradiating amplified light beam that interacts with a target material; a first sensor that senses light from the first channel; a second sensor that senses light from the second channel and the third channel, the second sensor having a lower acquisition rate than the first sensor; and an electronic processor coupled to a computer-readable storage medium, the medium storing instructions that, when executed, cause the processor to: receive data from the first sensor and the second sensor, and determine, based on the received data, a location of the irradiating amplified light beam relative to the target material in more than one dimension.

Abstract: A lithographic apparatus includes a patterning device support to support a patterning device to form a patterned radiation beam, the patterning device support including a moveable structure movably arranged with respect to an object, a patterning device holder movably arranged relative to the movable structure and holding the patterning device, an actuator to move the movable structure relative to the object, and an ultra short stroke actuator to move the patterning device holder relative to the movable structure; a substrate support to hold a substrate; and a projection system to project the patterned radiation beam onto the substrate, a position measurement system for measuring a substrate positional error which is a difference between a desired position and an actual position of the substrate relative to a reference object; and a controller to move the actuator and the ultra short stroke actuator based on the substrate positional error.

Abstract: A substrate holder for use in a lithographic apparatus. The substrate holder comprises a main body, a plurality of burls and a heater and/or a temperature sensor. The main body has a surface. The plurality of burls project from the surface and have end surfaces to support a substrate. The heater and/or temperature sensor is provided on the main body surface. The substrate holder is configured such that when a substrate is supported on the end surfaces, a thermal conductance between the heater and/or temperature sensor and the substrate is greater than a thermal conductance between the heater and/or temperature sensor and the main body surface.

Abstract: An immersion lithographic apparatus has a surface that in use is contacted by the immersion liquid and the surface has a surface roughness Ra that is less than or equal to 0.2 ?m. Immersion liquid on the surface may have a contact angle of 60° or greater. The surface may be able to maintain its properties so that immersion liquid on the surface may have the contact angle for a prolonged period of immersion in the immersion liquid.

Abstract: A control system for controlling a position or position related quantity of an object is provided. A measurement system is configured to measure a position or position related quantity of the object. A controller is configured to provide a control signal on the basis of the measured position or position related quantity. A actuator actuates the object on the basis of the control signal. A filter unit, which may be a partial order filter unit, filters the measured position or position related quantity.

Abstract: An article support is constructed to support an article. The article support includes a back fill structure constructed to supply and extract a thermal buffering fluid to and from the article support. The back fill structure is connected to an extraction duct that is constructed and arranged to extract at least a gas phase of the thermal buffering fluid from the back fill structure. The back fill structure is connected to a supply duct, constructed and arranged to supply a liquid phase of the thermal buffering fluid to the back fill structure. The back fill structure is arranged to have the thermal buffering fluid brought in a combined liquid and gas phase to thermally connect with the article.

Abstract: In a method of determining the focus of a lithographic apparatus used in a lithographic process on a substrate, the lithographic process is used to form a structure on the substrate, the structure having at least one feature which has an asymmetry in the printed profile which varies as a function of the focus of the lithographic apparatus on the substrate. A first image of the periodic structure is formed and detected while illuminating the structure with a first beam of radiation. The first image is formed using a first part of non-zero order diffracted radiation. A second image of the periodic structure is formed and detected while illuminating the structure with a second beam of radiation. The second image is formed using a second part of the non-zero order diffracted radiation which is symmetrically opposite to the first part in a diffraction spectrum.

Abstract: An apparatus includes a drive laser system producing an amplified light beam of pulses that travels along a drive axis; a beam delivery system that directs the amplified light beam of pulses toward a target region; a target material delivery system that provides a target mixture containing a target material in the target region; two or more sensors radially separated from a main axis that crosses the target region, the two or more sensors being configured to detect energy of ultraviolet electromagnetic radiation emitted from a plasma state of the target material when the amplified light beam of pulses intersects the target mixture; and a controller that receives the output from the two or more sensors. The controller is configured to estimate a relative radial alignment between the target mixture and the drive axis within the target region based on an analysis of the detected energy.

Abstract: A scatterometer for measuring a property of a substrate includes a focus sensing arrangement including an arrangement (65) that directs a first beam of radiation onto a focusing arrangement, to be detected by a focus sensor arrangement (61). A focus controller (67) provides control signals representative of the relative positions of the focusing arrangement (15, 69) and the substrate (W), which are required to focus the first beam of radiation on the substrate. An actuator arrangement adjusts the position of the focusing arrangement dependent on the control signals. An irradiation arrangement directs a second beam of radiation onto the substrate using the focusing arrangement, a measurement detector (18) detecting the second radiation beam after reflection from the substrate. A focus offset arrangement adjusts the focus produced by the focusing arrangement to compensate for an offset between the focusing of the first beam of radiation and the second beam of radiation.

Abstract: A computer-implemented method for obtaining values of one or more design variables of one or more design rules for a pattern transfer process comprising a lithographic projection apparatus, the method comprising. simultaneously optimizing one or more design variables of the pattern transfer process and the one or more design variables of the one or more design rules. The optimizing comprises evaluating a cost function that measures a metric characteristic of the pattern transfer process, the cost function being a function of one or more design variables of the pattern transfer process and one or more design variables of the one or more design rules.

Abstract: A method of, and associated apparatus for, determining focus corrections for a lithographic projection apparatus. The method comprises exposing a plurality of global correction fields on a test substrate, each comprising a plurality of global correction marks, and each being exposed with a tilted focus offset across it; measuring a focus dependent characteristic for each of the plurality of global correction marks to determine interfield focus variation information; and calculating interfield focus corrections from the interfield focus variation information.

Abstract: A lithographic apparatus having a first outlet to provide a thermally conditioned fluid with a first flow characteristic to at least part of a sensor beam path, and a second outlet associated with the first outlet and to provide a thermally conditioned fluid with a second flow characteristic, different to the first flow characteristic, adjacent the thermally conditioned fluid from the first outlet.

Abstract: A liquid supply system for an immersion lithographic apparatus provides a laminar flow of immersion liquid between a final element of the projection system and a substrate. A control system minimizes the chances of overflowing and an extractor includes an array of outlets configured to minimize vibrations.

Abstract: The invention relates to a lithographic apparatus arranged to transfer a pattern from a patterning device onto a substrate, wherein apparatus is operable to measure higher-order distortions and/or image plane deviations of the patterning device, apparatus comprising: a device for transmission image detection; and a processor configured and arranged to model higher-order distortions of the patterning device using signals received from the device for transmission image detection; wherein patterning device has a main imaging field, and a perimeter and apparatus is operable to model higher-order distortions using signals resultant from alignment structures comprised in perimeter and/or in the imaging field.

Abstract: A lithographic apparatus having a component that moves in a first direction, the component including a passive gas flow system. The passive gas flow system has a gas inlet to drive gas into the passive gas flow system when the component moves in the first direction and a gas outlet, connected to the gas inlet by a gas conduit, to direct the gas that is driven into the passive gas flow system in a certain direction.

Abstract: The invention relates to detecting targets located within patterns. The invention operates in the pupil plane by filtering the fourier transform from the surrounding pattern. In particular the method includes performing a fourier transform on reflected radiation data to form fourier transform data; removing portions of the fourier transform data which correspond to the target to form reduced fourier transform data; interpolating the portions of the reduced fourier transform data which were removed, to form product fourier transform data; and subtracting the product fourier transform data from the fourier transform data.

Abstract: A sensor for use in lithographic apparatus of an immersion type and which, in use, comes into contact with the immersion liquid is arranged so that the thermal resistance of a first heat path from a transducer of the sensor to a temperature conditioning device is less than the thermal resistance of a second heat flow path from the transducer to the immersion liquid. Thus, heat flow is preferentially towards the temperature conditioning device and not the immersion liquid so that temperature-induced disturbance in the immersion liquid is reduced or minimized.

Abstract: A module for producing extreme ultraviolet radiation, including an extreme ultraviolet radiation-emitting source, the source being provided with a supply configured to supply a fluid of an ignition material to a predetermined target ignition position and a target-igniting mechanism constructed and arranged to produce a plasma from the ignition material at the target ignition position, the plasma emitting the extreme ultraviolet radiation; a collector mirror constructed and arranged to focus radiation emitted by the plasma at a focal point; and a heat sink having a thermal energy-diverting surface constructed and arranged to divert thermal energy away from the target ignition position, wherein the heat sink is located at a position proximate the target ignition position.