Abstract: In a lithographic projection apparatus, a liquid supply system maintains liquid in a space between the projection system and the substrate. The liquid supply system may further include a de-mineralizing unit, a distillation unit, a de-hydrocarbonating unit, a UV radiation source, and/or a filter configured to purify the liquid. A gas content reduction device may be provided to reduce a gas content of the liquid. A chemical may be added to the liquid using an adding device to inhibit lifeform growth and components of the liquid supply system may be made of a material which is non-transparent to visible light such that growth of lifeforms may be reduced.

Abstract: A support constructed to support a patterning object, the patterning object being capable of imparting the radiation beam with a pattern in its cross-section to form a patterned radiation beam, is disclosed, wherein the support comprises a plurality of structures having a plurality of local contact areas, respectively, on which the patterning object is disposed, in use, and a clamp configured to clamp the patterning object to the plurality of contact areas, wherein each structure is configured so that a local shear stiffness of each local contact area is substantially balanced with a local friction limit at each local contact area, respectively.

Abstract: Method to calibrate a substrate table position in a lithographic apparatus includes providing a substrate on the substrate table with a two dimensional arrangement of patterns; positioning the substrate table with a positioning system; measuring positions of the substrate table in at least two dimensions with a position measurement system; reading out the arrangement of patterns as a function of the measured positions of the substrate table with a pattern read out system to obtain pattern read out results; deriving position errors as a function of the measured positions of the substrate table compared with the pattern read out results; calibrating the positioning system using the position errors, the calibrating including determining drift influences of the positioning system, correcting the position errors as a function of the corresponding two dimensional position of the substrate table with the determined drift influences, and calibrating the positioning system with the corrected position errors.

Abstract: A difficulty of contamination interfering with a grid plate positional measurement system is addressed. In one embodiment contamination is prevented from coming into contact with the grating or the sensor. In an embodiment, surface acoustic waves are used to detach contamination from a surface of the grating or sensor.

Abstract: A lithographic system and method are provided that allow for variations of a basic device design to be generated without substantially increasing the cost of the data path hardware. The lithographic apparatus includes an array of individually controllable elements, a control system, a first data buffer, and a second data buffer. The control system provides control signals to the array of individually controllable elements. The first data buffer stores pattern data that corresponds to a pattern to be exposed on a plurality of areas on the substrate. The second data buffer stores pattern variation data, corresponding to at least one change to a part of the pattern. The control system is configured, such that at least one variation of the pattern is exposed on one of the areas on the substrate with the pattern variation data.

Abstract: A lithographic apparatus is disclosed that includes a first gas shower configured to supply a first gas flow to an interior space of the apparatus, and a second gas shower configured to supply a second gas flow to the interior space of the apparatus, the gas showers configured to direct the first gas flow and the second gas flow at least partly towards each other. Also, a method for conditioning an interior space of a device manufacturing apparatus is provided that includes supplying a first conditioned gas flow and a second conditioned gas flow to the interior space, such that the first conditioned gas flow and the second conditioned gas flow are at least partly directed to each other.

Abstract: A system for controlling the radiation dose in a pulse of radiation having a relatively large dose, in which a pulsed beam of radiation is divided into a plurality of pulsed sub-beams of radiation and the radiation dose of the pulses is adjusted after the radiation beam has been divided.

Abstract: A system and method are used to form incoherent beams from a coherent beam. A system comprises a source of radiation and a reflective loop system. The source of radiation produces a coherent or partially coherent beam. The reflective loop system received the partially coherent beam and reflects the partially coherent beam through a loop, or alternatively through non-overlapping loops, to form an incoherent beam.

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 sensor configured to measure a height level, curvature and/or angle of a surface of a patterning device supported on the support.

Abstract: A lithographic apparatus and device manufacturing method makes use of a liquid confined in a reservoir between the projection system and the substrate. Bubbles forming in the liquid from dissolved atmospheric gases or from out-gassing from apparatus elements exposed to the liquid are detected and/or removed so that they do not interfere with exposure and lead to printing defects on the substrate. Detection may be carried out by measuring the frequency dependence of ultrasonic attenuation in the liquid and bubble removal may be implemented by degassing and pressurizing the liquid, isolating the liquid from the atmosphere, using liquids of low surface tension, providing a continuous flow of liquid through the imaging field, and/or phase shifting ultrasonic standing-wave node patterns.

Abstract: A method of increasing a depth of focus of a lithographic apparatus is disclosed. The method includes forming diffracted beams of radiation using a patterning device pattern; and transforming a phase-wavefront of a portion of the diffracted beams into a first phase-wavefront having a first focal plane for the lithographic apparatus, and a second phase-wavefront having a second, different focal plane, wherein the transforming comprises: subjecting a phase of a first portion of a first diffracted beam and a phase of a corresponding first portion of a second diffracted beam to a phase change which results in an at least partial formation of the first phase-wavefront, and subjecting a phase of a second portion of the first diffracted beam and a phase of a corresponding second portion of the second diffracted beam to a phase change which results in an at least partial formation of the second phase-wavefront.

Abstract: A lithographic apparatus includes two stages that are each configured to hold a substrate, wherein each stage is provided with a short stroke module to move a table with a substrate and a long stroke module to move the short stroke module of that stage. The lithographic apparatus includes a swap bridge to couple the stages, and wherein, in use, in a first configuration, the stages are moveable with respect to each other, and wherein, in use, in a second configuration, the stages are coupled via the swap bridge to make a joint movement.

Abstract: A device is arranged to measure a quantity relating to radiation. The device includes a sensor configured to measure the quantity, a screen arranged to protect the sensor from incoming particles emitted from a source configured to emit extreme ultraviolet radiation, and a mirror configured to redirect extreme ultraviolet radiation emitted by the source, past the screen, to the sensor.

Abstract: Each target used in a method of measuring overlay using a scatterometer includes a first portion and a second portion, the first portion has features varying only in a first direction and the second portion has features only varying in a second direction. The first and second directions are orthogonal, thus eliminating cross talk between the directions, and improving the accuracy of overlay error calculations.

Abstract: A lithographic apparatus has an assembly to exchange optical elements in a pupil plane of its projection system. The optical elements may be pupil filters and may conform to the physical dimensions specified for a reticle standard, e.g. having sides substantially equal to 5, 6 or 9 inches.

Abstract: A method is described that includes illuminating a patterning device pattern with a radiation beam having a symmetric illumination mode, the patterning device pattern comprising a first pattern feature that substantially diffracts radiation of the radiation beam, and a second pattern feature that does not substantially diffract radiation of the radiation beam, introducing an asymmetry, relative to an optical axis, in the substantially diffracted radiation using a phase modulation element, illuminating a radiation beam receiving element with radiation emanating from the phase modulation element to form a receiving element pattern that is related to the patterning device pattern, the receiving element pattern having first and second receiving element pattern features related to the first and second pattern features respectively, and determining information at least indicative of a focal property from positional information regarding the relative positions of the first and second receiving element pattern featur

Abstract: A method for manufacturing a device includes providing a substrate, the substrate including a plurality of exposure fields, each exposure field including one or more target portions and at least one mark structure, the mark structure being arranged as positional mark for the exposure field; scanning and measuring the mark of each exposure field to obtain alignment information for the respective exposure field; determining an absolute position of each exposure field from the alignment information for the respective exposure field; determining a relative position of each exposure field with respect to at least one other exposure field by use of additional information on the relative parameters of the exposure field and the at least one other exposure field relative to each other; and combining the absolute positions and the determined relative positions into improved absolute positions for each of the plurality of exposure fields.

Abstract: A control system to control a position quantity of a movable object in dependency of signals provided by a sensor representing an actual position quantity of the moveable object, the control system being configured to provide a drive signal to an actuator which is able to apply forces to the moveable object, the control system including a set-point generator to provide a reference signal; a subtractor to provide an error signal, the error signal being the difference between the reference signal and the signals provided by the sensor; a control unit to provide a drive signal to the actuator in dependency of the error signal, wherein the control unit comprises a nonlinear controller to improve a low-frequency disturbance suppression, and wherein the control unit further includes a compensator to at least partially compensate the deterioration of the high-frequency behavior caused by the nonlinear controller.

Abstract: A gas gauge has a gas delivery tube arranged to determine a distance to an object. The gas delivery tube includes a gas conduit through which a suitable measurement gas is supplied. The measurement gas leaves the gas delivery tube under pressure via an outlet and impinges on the object in an interaction area, wherein a pressure of a recoiled gas is measured by a pressure detector. A gas having a low atomic number may be used. The pressure sensor may include a membrane positioned in the gas delivery tube at least partially enveloping the gas conduit at or near the gas outlet. The pressure sensor may include a membrane disk arranged about the gas conduit. The pressure sensor may include a suitable plurality of pressure elements arranged in a substantially common plane and which may be spaced apart yet enveloping the gas conduit.

Abstract: A radiation source includes an anode and a cathode for creating a discharge in a vapor in a space between anode and cathode and to form a plasma of a working vapor so as to generate electromagnetic radiation. The cathode defines a hollow cavity in communication with the discharge region through an aperture that has a substantially annular configuration around a central axis of said radiation source so as to initiate said discharge. A driver vapor is supplied to the cathode cavity and the working vapor is supplied in a region around the central axis in between anode and cathode.