Abstract: A lithographic apparatus includes a projection system configured to project a patterned beam of radiation onto a substrate. The projection system being provided with an opening through which the patterned beam of radiation may pass. At least part of the opening comprises a sloped surface of a wall of the projection system and a sloped surface of a mirror of the projection system.

Abstract: A CD-pitch dependency for a lithographic pattern printing process is related to the spectral intensity distribution of radiation used for projecting the pattern. A CD-pitch dependency can vary from one system to another. This can result in an iso-dense bias mismatch between systems. The invention addresses this problem by providing a lithographic apparatus including an illumination system for providing a projection beam of radiation, a projection system for projecting a patterned beam onto a target portion of a substrate, and a substrate table for holding the substrate, with a controller to provide an adjustment of the spectral distribution of radiant intensity of the projection beam. The adjustment of the spectral intensity distribution is based on data relating to an iso dense bias, and comprises a broadening of the spectral bandwidth or a change of shape of the spectral intensity distribution.

Abstract: A method of controlling an element of an array of individually controllable elements. The method includes varying a frequency of a driving voltage with which the element is driven.

Abstract: A lithographic apparatus is provided in which exposure is carried out by projecting through an aqueous solution of alkali metal halide(s), the solution being in contact with the substrate to be exposed.

Abstract: A lithographic apparatus is provided that has a sensor at substrate level, the sensor including a radiation receiver, a transmissive plate supporting the radiation receiver, and a radiation detector, wherein the sensor is arranged to avoid loss of radiation between the radiation receiver and a final element of the radiation detector.

Abstract: An optical window is used to facilitate best performance for imaging an object placed in a separate ambiance. The window can be in a particle detection system, comprising a separator between first and second environments. The separator comprises an opening and an optical element located within the opening. An object is located in the second environment. An objective lens is located in the first environment and a detector is located in the second environment and is configured to detect particles on a surface of the object.

Abstract: The present invention relates to lithographic apparatuses and processes, and more particularly to multiple patterning lithography for printing target patterns beyond the limits of resolution of the lithographic apparatus. Self-aligned assist pattern (SAP) is derived from original design layout in an automated manner using geometric Boolean operations based on some predefined design rules, and are included in the mask layout for efficient self-alignment of various sub-layouts of the target pattern during a multiple patterning lithography process. SAP can be of any shape and size, and can have continuous features (e.g., a ring), or discontinuous (e.g., bars not connected to each other) features. An end-to-end multiple patterning lithography using spacer and SAP may use positive tone lithography, and/or negative tone lithography for line and/or space printing.

Abstract: A lithographic apparatus includes an illumination system configured to condition a radiation beam; a support constructed to support a patterning device, the device being capable of imparting the beam with a pattern in its cross-section to form a patterned radiation beam; a substrate table constructed to hold a substrate; a stage system to position the table relative to a reference structure; a projection system configured to project the patterned radiation beam onto a target portion of the substrate; an optical measurement system including a sensor part and an optical part, the optical part being configured to optically interact with the patterned radiation beam and to transmit a result from the interaction as output to the sensor part, wherein the optical part is arranged on the table, and the sensor part is arranged on the stage system or the reference structure.

Abstract: A measurement system is configured to derive a position quantity of an object, the measurement system includes at least one position quantity sensor configured to provide respective position quantity measurement signals; a position quantity calculator configured to determine a position quantity of the object from the position quantity measurement signal, wherein the position quantity calculator includes a torsion estimator configured to estimate a torsion of the object, the position quantity calculator being configured to correct the determined position quantity of the object for the estimated torsion.

Abstract: A lithographic apparatus includes an illumination system configured to condition a radiation beam; a support constructed to support a patterning device, the patterning device being capable of imparting the radiation beam with a pattern in its cross-section to form a patterned radiation beam; a substrate table constructed to hold a substrate; a projection system configured to project the patterned radiation beam onto a target portion of the substrate; and a cooling system to cool a part of the lithographic apparatus with increased cooling capabilities to reduce the heat transfer from the part to other parts of the apparatus.

Abstract: A method is provided for transferring a substrate from a first substrate holder, e.g., a pre-alignment unit, to a second substrate holder, e.g., a substrate table in a lithographic apparatus, by means of a transfer unit on the basis of transfer data available thereto. First, the substrate is provided on the first substrate holder. Subsequently, a position error of the substrate is measured, and positioning adjustment data are calculated based on the position error as measured. Then, the second substrate holder is moved relative to a reference position thereof in accordance with the positioning adjustment data. Finally, the substrate is transferred by means of the transfer unit from the first substrate holder to the second substrate holder in accordance with the transfer data, and placed on the second substrate holder as moved.

Abstract: An illumination system having an array of individually controllable optical elements is disclosed, wherein each element is moveable between a plurality of orientations which may be selected in order to form desired illumination modes. The illumination system includes a controller to control orientation of one or more of the elements, the controller configured to apply force to the one or more elements which at least partially compensates for force applied to the one or more elements by a burst of radiation incident upon the one or more elements.

Abstract: A lithographic method for irradiating resist on a substrate, the resist filling a region located between a first element located on the substrate, and a second element located on the substrate, the first element having a first length, a first width, and a first height, the second element having a second length, a second width, and a second height, the first height being substantially equal to the second height, the first length being substantially parallel to the second length, and extending in a first direction, a distance between facing sidewalls of the first element and the second element that defines the region filled with resist being less than a wavelength of radiation used to irradiate the resist, the method including irradiating the resist with elliptically polarized radiation, the elliptically polarized radiation being configured such that, at the first height and second height, the elliptically polarized radiation is polarized perpendicular to the first direction, substantially perpendicular to the

Abstract: A method for thermally conditioning an optical element includes irradiating the optical element with radiation, not-irradiating the optical element with the radiation, allowing heat flow between the optical element and a conditioning fluid that is held in a conditioning fluid reservoir, and providing a fluid flow of the conditioning fluid, to supply thermally conditioned fluid to the reservoir. A flow rate of the fluid during the irradiating of the optical element is lower than a flow rate of the fluid when the optical element is not-irradiated.

Abstract: A porous member is used in a liquid removal system of an immersion lithographic projection apparatus to smooth uneven flows. A pressure differential across the porous member may be maintained at below the bubble point of the porous member so that a single-phase liquid flow is obtained. Alternatively, the porous member may be used to reduce unevenness in a two-phase flow.

Abstract: A method for forming a mark structure on a substrate comprising a plurality of lines. The lines extend parallel to each other in a first direction and are arranged with a pitch between each pair of lines that is directed in a second direction perpendicular to the first direction. The pitch between each pair of selected lines differs from the pitch between each other pair of selected lines.

Abstract: A position sensor is configured to measure a position data of a target. The position sensor includes a radiation source configured to irradiate a radiation beam, a first grating configured to diffract the radiation beam in a first diffraction direction into at least a first order diffraction beam, and a second grating, arranged in an optical path of the first order diffraction beam, the second grating being configured to diffract the first order diffraction beam diffracted at the first grating in a second diffraction direction substantially perpendicular to the first diffraction direction. The second grating is connected to the target. A first detector is configured to detect at least a part of the beam diffracted by the first grating, and at least one second detector is configured to detect at least part of the beam diffracted by the first grating and the second grating.

Abstract: Scatterometry method and apparatus are useful in a lithographic apparatus and device manufacturing. A back focal plane diffraction intensity image of a measurement projection system configured to project a radiation beam onto a target portion of a substrate is measured. A beam of radiation having a first wavelength is directed to the substrate. A diffraction image of a zeroth diffraction order and higher order diffraction from a diffraction structure in the substrate is provided. A first layer (4) of the diffractionstructure provides a diffraction image having only a zeroth diffraction order. A second layer (5) has a periodic structure (6a, 6b) configured such that a lowest spatial frequency of the periodic structure is lower than spatial frequencies of interest of the first structure. From the diffraction image originating from diffraction of the radiation beam in both the first and second layer a critical dimension metrology parameter is determined.

Abstract: A method of preparing components for use in a vacuum chamber of a lithographic apparatus is disclosed. The method includes coating the component with a non-metallic material. The method may further include treating the coating so as to harden the coating. Preferably, the coating material is a hydrogen silsesquioxane (HSQ), which may be applied via spraying, brushing, or spinning and can be treated by heating or by irradiation with an electron beam. The resulting components strongly reduce outgassing of water and hydrocarbons when subjected to a vacuum environment.

Abstract: An apparatus, suited, for example, for extreme ultraviolet lithography, includes a radiation source and a processing organ for processing the radiation from the radiation source. Between the radiation source and the processing organ a filter is placed which, in the radial direction from the radiation source, comprises a plurality of foils or plates.