Abstract: A device manufacturing method is provided. The method includes generating a first patterned beam, projecting the first patterned beam onto a substrate to form a first plurality of spot exposures on the substrate, scanning the substrate in a direction while projecting the first patterned beam, generating a second patterned beam, projecting the second patterned beam onto the substrate to form a second plurality of spot exposures on the substrate, and alternating spot exposures of the first plurality of spot exposures with respective spot exposures of the second plurality of spot exposures.

Abstract: A sealing member is provided to prevent immersion liquid ingress to a gap between components. The sealing member has a plastic or polymer sealing portion that is adhered to the components forming the gap being sealed. The sealing member is constructed so as to reduce the force-coupling, in particular the time-related force-coupling, between the components being sealed.

Abstract: Embodiments of the invention related to lithographic apparatus and methods. A lithographic method comprises calculating a laser metric based on a spectrum of laser radiation emitted from a laser to a lithographic apparatus together with a representation of an aerial image of a pattern to be projected onto the substrate by the lithographic apparatus, and using the laser metric to modify operation of the laser or adjust the lithographic apparatus, and projecting the pattern onto the substrate.

Abstract: A table for a lithographic apparatus, the table having an encoder plate located on the table, a gap between the encoder plate and a top surface of the table, the gap located radially inward of the encoder plate relative to the periphery of the table, and a fluid extraction system with an opening in the surface of the gap to extract liquid from the gap.

Abstract: A meniscus pinning device has a plurality of openings through which liquid and gas from the environment are extracted. The openings are of an intermediate size, having a maximum cross-sectional dimension (e.g., diameter) in the range of from about 75 ?m to about 150 ?m.

Abstract: System and methods estimate model parameters of a lithographic apparatus and control lithographic processing by a lithographic apparatus. An exposure is performed using a lithographic apparatus across a wafer. A set of predetermined wafer measurement locations is obtained. Discrete orthonormal polynomials are generated using the predetermined substrate measurement locations. The overlay errors arising from the exposure are measured at the predetermined locations to obtain overlay measurements. The estimated model parameters of the lithographic apparatus are calculated from the overlay measurements by using the discrete orthogonal polynomials as a basis function to model the overlay across the wafer. Finally, the estimated model parameters are used to control the lithographic apparatus in order to provide corrected overlay across the wafer.

Abstract: An imprint lithography template is disclosed. The imprint lithography template includes a plurality of pattern features extending from a plane of a body of the imprint lithography template, and away from that body, the pattern features to be used to apply a pattern into an imprintable medium. The imprint lithography template further includes a plurality of assist features in the form of recesses extending from the plane of that body of the imprint lithography template, and into that body. A method for forming the assist features in the imprint lithography template, using self-assembled block copolymers as an etch resist, is also disclosed.

Abstract: A lithographic apparatus is disclosed having a deformable lens element through which a patterned radiation beam is arranged to pass before reaching a substrate and having a deformable lens actuator configured to transmit a combination of a force substantially parallel to the optical axis of the projection system and a localized torque about an axis substantially perpendicular to the optical axis independently at a plurality of sub-regions on the deformable lens element.

Abstract: To inspect all portions of the substrate the substrate table can be moved rotationally and linearly. Furthermore the detector can be moved rotationally. This enables all portions of a surface of the substrate to be inspected from all angles in a plane parallel to the substrate. Less linear motion is needed, so the apparatus occupies a smaller volume and generates smaller vibrations.

Abstract: To inspect all portions of the substrate, the substrate table can be moved rotationally and linearly. Furthermore, the detector can be moved rotationally. This allows all portions of a surface of the substrate to be inspected from all angles in a plane parallel to the substrate. In one example, as less linear motion is needed, the apparatus occupies a smaller volume and generates smaller vibrations.

Abstract: A model-based tuning method for tuning a first lithography system utilizing a reference lithography system, each of which has tunable parameters for controlling imaging performance. The method includes the steps of defining a test pattern and an imaging model; imaging the test pattern utilizing the reference lithography system and measuring the imaging results; imaging the test pattern utilizing the first lithography system and measuring the imaging results; calibrating the imaging model utilizing the imaging results corresponding to the reference lithography system, where the calibrated imaging model has a first set of parameter values; tuning the calibrated imaging model utilizing the imaging results corresponding to the first lithography system, where the tuned calibrated model has a second set of parameter values; and adjusting the parameters of the first lithography system based on a difference between the first set of parameter values and the second set of parameter values.

Abstract: A method for calibrating an auxiliary sensor system is provided. The auxiliary sensor system measures a position of a grating relative to a reference, the grating forming part of an encoder measurement system. The encoder measurement system is adapted to measure a position of a substrate table of a lithographic apparatus and further comprises a sensor mounted to the substrate table. The method comprises exciting the grating to make a movement in at least one measurement direction of the auxiliary sensor system, obtaining an auxiliary sensor system output signal from the sensor system during the movement, and adjusting a parameter of the auxiliary sensor system based on the output signal obtained during the movement to thereby calibrate the auxiliary sensor system.

Abstract: A method of making an imprint template includes providing a transfer layer on a substrate and providing a layer of imprintable medium on the transfer layer, using a master imprint template to imprint a pattern into the imprintable medium, polymerizing the imprintable medium by exposing it to actinic radiation, then etching the resulting polymer layer, the transfer layer and the substrate such that the imprinted pattern is transferred to the substrate, the substrate thereby becoming an imprint template bearing a pattern which is the inverse of a pattern provided on the master imprint template.

Abstract: A target for measuring an overlay error or a critical dimension of a substrate comprises a grating. In one example, lines of the grating are arranged at an angle of about 45° with respect to edges of the target.

Abstract: A lithographic device includes a cooling device for removing heat from a motor. The cooling device has a cooling element provided in thermal contact with at least part of the motor. The cooling device further has a cooling duct assembly with a supply duct to supply a cooling fluid to the cooling element, and a discharge duct to discharge the cooling fluid from the cooling element. A pump causes the cooling fluid to flow through at least part of the cooling duct assembly. A flow control device controls a flow rate of the cooling fluid through at least part of the cooling duct assembly, to maintain a predetermined average temperature of the cooling fluid in the cooling element.

Abstract: A fluid handling structure for a lithographic apparatus, the fluid handling structure successively having, at a boundary from a space configured to comprise immersion fluid to a region external to the fluid handling structure: an extractor having at least one opening arranged in a first line that, in use, is directed towards a substrate and/or a table; and a liquid manipulator on a surface that, in use, faces the substrate and/or table to reduce the chance of droplets on the surface from coalescing.

Abstract: A lithographic system includes a lithographic apparatus comprising a projection system which projects a patterned radiation beam onto a target portion of a substrate and an alignment system which measures the position of a feature of the pattern on the substrate at a number of locations over the substrate. A controller compares the measured positions with points on a grid of values and extrapolates values for intermediate positions on the substrate based on values of corresponding intermediate points on the grid, so as to provide an indication of the intermediate positions on the substrate and their displacements relative to the grid. The grid is based on at least one orthogonal basis function, the measurement on the substrate being performed at positions corresponding to the root values of the at least one orthogonal basis function.

Abstract: A lens element, for use in a projection system, includes a concave side. The lens element further includes a membrane and a nozzle, the membrane at least covering the concave side of the lens element. The nozzle is arranged for supplying and/or removing a liquid and/or a gas in between the concave side and the membrane.

Abstract: A lithographic projection apparatus is disclosed in which measures are taken to prevent or reduce the presence of bubbles in liquid through which the projection beam radiates. This may be done, for example, by ensuring that a gap between a substrate and a substrate table is filled with immersion liquid or by causing a localized flow radially outwardly from the optical axis in the vicinity of the edge of the substrate.

Abstract: A device manufacturing method includes a transfer of a pattern from a patterning device onto a substrate. The device manufacturing method further includes transferring a pattern of a main mark to a base layer for forming an alignment mark; depositing a pattern receiving layer on the base layer; in a first lithographic process, aligning, by using the main mark, a first mask that includes a first pattern and a local mark pattern, and transferring the first pattern and the local mark pattern to the pattern receiving layer; aligning, by using the local mark pattern, a second mask including a second pattern relative to the pattern receiving layer; and in a second lithographic process, transferring the second pattern to the pattern receiving layer; the first and second patterns being configured to form an assembled pattern.