Abstract: A lithographic apparatus includes: an object that is moveable in at least one direction; a control system to move the object in the at least one direction, wherein the control system is arranged to control movement of the object in the at least one direction in a frequency range of interest; and a conduit provided with a fluid, wherein the conduit is arranged on or in the object in a pattern, and wherein the pattern is such that an acceleration of the object in the at least one direction causes an acceleration pressure profile in the fluid along the conduit, the acceleration pressure profile not matching with a resonance pressure profile that corresponds to a standing wave mode in the fluid with a resonance frequency in the frequency range of interest.

Abstract: A substrate holder for a lithographic apparatus has a main body having a thin-film stack provided on a surface thereof. The thin-film stack forms an electronic or electric component such as an electrode, a sensor, a heater, a transistor or a logic device, and has a top isolation layer. A plurality of burls to support a substrate are formed on the thin-film stack or in apertures of the thin-film stack.

Abstract: A method of determining a position of an imprint template in an imprint lithography apparatus is disclosed. In an embodiment, the method includes illuminating an area of the imprint template in which an alignment mark is expected to be found by scanning an alignment radiation beam over that area, detecting an intensity of radiation reflected or transmitted from the area, and identifying the alignment mark via analysis of the detected intensity.

Abstract: A multi-stage system includes a stator including a plurality of electric coils; a first stage including a first magnet assembly, the first stage moveable relative to the stator; a second stage including a second magnet assembly, the second stage moveable relative to the stator; a controller configured to position the first and the second stage relative to the stator by activating, respectively, a first subset of the plurality of electric coils to interact with the first magnet assembly and a second subset of the plurality of electric coils to interact with the second magnet assembly, the controller adapted to prevent at least one electric coil, to be simultaneously shared by the first and the second subset to position the first and the second stage on the stator, from activating.

Abstract: Disclosed is component for a radiation source, said radiation source being operable to generate radiation from a fuel, said component having a surface comprising a plurality of first regions that have a high wettability by said fuel, separated by second regions which have a low wettability by said fuel. Said component may comprise a screening element for a droplet generator or contamination trap, for example.

Abstract: A fluid handling structure for a lithographic apparatus, the fluid handling structure having, at a boundary from a space configured to contain immersion fluid to a region external to the fluid handling structure: a meniscus pinning feature to resist passage of immersion fluid in a radially outward direction from the space; a plurality of gas supply openings in a linear array at least partly surrounding and radially outward of the meniscus pinning feature; and a gas recovery opening radially outward of the plurality of gas supply openings in a linear array.

Abstract: The present invention determines property of a target (30) on a substrate (W), such as a grating on a wafer. An inspection apparatus has an illumination source (702, 710) with two or more illumination beams (716, 716?, 716?, 716??) in the pupil plane of a high numerical aperture objective lens (L3). The substrate and target are illuminated via the objective lens from different angles of incidence with respect to the plane of the substrate. In the case of four illumination beams, a quad wedge optical device (QW) is used to separately redirect diffraction orders of radiation scattered from the substrate and separates diffraction orders from the two or more illumination beams. For example four 0th diffraction orders are separated for four incident directions. After capture in multimode fibers (MF), spectrometers (S1-S4) are used to measure the intensity of the separately redirected 0th diffraction orders as a function of wavelength. This may then be used in determining a property of a target.

Abstract: A system detects targets located within patterns. It operates in the pupil plane by filtering the received signal from the surrounding pattern. A method includes illuminating a target and a surrounding pattern with radiation, detecting the radiation reflected by the target and the surrounding pattern and forming a first set of data based on the detected radiation, removing portions of the first set of data which correspond to the target to form reduced data, interpolating the remaining portions of the reduced data over the removed portions to form product data, and subtracting the product data from the first set of data to form target data.

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 spectral purity filter is configured to transmit extreme ultraviolet (EUV) radiation and deflect or absorb non-EUV secondary radiation. In an embodiment, the spectral purity filter includes a body of material highly transmissive of EUV radiation and a layer of material highly reflective of non-EUV secondary radiation located on a radiation incident side of the body. In an embodiment, the spectral purity filter includes a body of material highly transmissive of EUV radiation and a layer of high emissivity material on an end of the body.

Abstract: A field manipulator to provide high resolution control of position in the XY plane and/or focus control. The field manipulator includes a plate located between the patterning device and the substrate. Control of the XY position is provided by tilting of the plate, while control of the focus position may be provided by localized deformation of the plate. Both adjustments may be performed by one or more actuators that act upon one or more edges of the plate. In an embodiment, two substantially parallel plates are provided and focus control can be provided by changing the spacing between them. A liquid may be provided between the plates which may be temperature controlled to adjust the focus by changing the refractive index of the liquid.

Abstract: A lithographic apparatus is disclosed including a liquid supply system configured to at least partly fill a space between the projection system and the substrate with a liquid, an outlet configured to remove a mixture of liquid and gas passing through a gap between a liquid confinement structure of the liquid supply system and the substrate, and an evacuation system configured to draw the mixture through the outlet, the evacuation system having a separator tank arranged to separate liquid from gas in the mixture and a separator tank pressure controller, connected to a non-liquid-filled region of the separator tank, configured to maintain a stable pressure within the non-liquid-filled region.

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: A method including: determining recipe consistencies between one substrate measurement recipe of a plurality of substrate measurement recipes and each other substrate measurement recipe of the plurality of substrate measurement recipes; calculating a function of the recipe consistencies; eliminating the one substrate measurement recipe from the plurality of substrate measurement recipes if the function meets a criterion; and reiterating the determining, calculating and eliminating until a termination condition is met. Also disclosed herein is a substrate measurement apparatus, including a storage configured to store a plurality of substrate measurement recipes, and a processor configured to select one or more substrate measurement recipes from the plurality of substrate measurement recipes based on recipe consistencies among the plurality of substrate measurement recipes.

Abstract: Disclosed is a method of determining a correction for measured values of radiation diffracted from a target comprising a plurality of periodic structures, subsequent to measurement of the target using measurement radiation defining a measurement field. The correction acts to correct for measurement field location dependence in the measured values. The method comprises performing a first and second measurements of the periodic structures; and determining a correction from said first measurement and said second measurement. The first measurement is performed with said target being in a normal measurement location with respect to the measurement field. The second measurement is performed with the periodic structure in a shifted location with respect to the measurement field, said shifted location comprising the location of another of said periodic structures when said target is in said normal measurement location with respect to the measurement field.

Abstract: A sensor system configured to determine a position of a substrate having an edge. The sensor system includes a radiation source arranged to emit a radiation bundle, a reflective element, a detector device and a substrate table having a supporting surface for supporting the substrate. The supporting surface is at least partly along a plane. The radiation source and the detector device are arranged on a first side of the plane. The reflective element is arranged on a second side of the plane other than the first side. The reflective element is arranged to create a reflected bundle by reflecting the radiation bundle. The reflective element is arranged to illuminate the edge with the reflected bundle. The detector device is arranged to receive the reflected bundle.

Abstract: A lithographic projection apparatus is provided with a EUV radiation system that includes a source chamber, a supply constructed and arranged to supply a target material to a predetermined plasma formation position, an optical system formed by three or more mirrors arranged to establish a beam path extending to the target material when the target material is located at the predetermined plasma formation position, and a laser system constructed and arranged to provide a laser beam along the beam path for interaction with the target material to produce an EUV radiation-emitting plasma inside the chamber.

Abstract: An immersion liquid is provided comprising an ion-forming component, e.g. an acid or a base, which has a relatively high vapor pressure. Also provided are lithography processes and lithography systems using the immersion liquid.

Abstract: Disclosed is a method of monitoring a focus parameter during a lithographic process. The method comprises acquiring first and second measurements of, respectively first and second targets, wherein the first and second targets have been exposed with a relative best focus offset. The method then comprises determining the focus parameter from first and second measurements. Also disclosed are corresponding measurement and lithographic apparatuses, a computer program and a method of manufacturing devices.

Abstract: A magnetic device includes first and second parts, a first magnetic part, with a first magnetic polarization, coupled to the first part, a second magnetic part, with a second magnetic polarization, coupled to the second part and an additional magnetic part coupled to the first part and having an additional magnetic polarization. The first and second magnetic parts magnetically interact with each other. The first magnetic part exerts a first force on the second magnetic part, the second magnetic part exerts a second force on the first magnetic part and the first and second forces have opposite directions that are parallel to a reference direction. The first magnetic polarization is substantially parallel to the reference direction, the second magnetic polarization is substantially perpendicular to the reference direction, the additional magnetic polarization makes an angle with the first magnetic polarization and has a magnitude in a range of about 90°-270°.