Abstract: A method for determining an image of a mask pattern in a resist coated on a substrate, the method including determining an aerial image of the mask pattern at substrate level; and convolving the aerial image with at least two orthogonal convolution kernels to determine a resist image that is representative of the mask pattern in the resist.

Abstract: A method of depositing an imprintable medium onto a target area of a substrate for imprint lithography is disclosed. The method includes moving the substrate, a print head comprising a nozzle to eject an imprintable medium onto the substrate, or both, relative to the other in a first direction across the target area while ejecting a first series of droplets of imprintable medium onto the substrate and moving the substrate, the print head; or both, relative to the other in a second opposing direction across the target area while ejecting a second series of droplets of imprintable medium onto the substrate on or adjacent to droplets from the first series of droplets.

Abstract: During a multiple patterning process every nth element of the pattern is removed. The removal of the elements of the patterns happens after the pattern has been printed into the radiation sensitive material or etched into substrate. Advantageously, the original mask is not varied, and another exposure step is used to remove the elements of the pattern.

Abstract: A lithographic apparatus includes a stage to hold an object, the stage being moveable relative to a reference structure in a motion range; a magnet structure to provide a spatially varying magnetic field in at least a part of the motion range, the magnet structure being moveable relative to the reference structure and the stage; a first position measurement system to provide a first measurement signal corresponding to a position of the stage and/or the object in a measurement direction relative to the reference structure; a second position measurement system to provide a second measurement signal corresponding to a position of the stage relative to the magnet structure; and a data processor to correct the first measurement signal with a value dependent on the second measurement signal to provide a corrected first measurement signal representative of the position of the stage and/or the object relative to the reference structure in the measurement direction.

Abstract: A lithographic apparatus having a table including a target and/or a sensor and a liquid displacing device to displace liquid from the target and/or sensor using a localized gas flow is disclosed. The liquid displacement device may be positioned at various positions, e.g. mounted to a liquid handling device at an exposure station, adjacent or in a transfer path between the exposure station and a measurement station, at a load/unload station or adjacent a sensor.

Abstract: An object suitable for a plasma cleaning treatment in a plasma cleaning device, the object including a first outer surface area; a second outer surface area, wherein the object is constructed and arranged to cooperate with a removable cover such that the cover is connectable to the object to cover the second outer surface area, and wherein the object connected with the removable cover is adapted to be cleaned in the plasma cleaning device such that the plasma cleaning device is not exposed to particles of the second outer surface area and wherein the first outer surface area is cleaned in the plasma cleaning device.

Abstract: In an embodiment, there is provided a method of at least partially compensating for a deviation in a property of a pattern feature to be applied to a substrate using a lithographic apparatus. The method includes determining a desired phase change to be applied to at least a portion of a radiation beam that is to be used to apply the pattern feature to the substrate and which would at least partially compensate for the deviation in the property. The determination of the desired phase change includes determining a desired configuration of a phase modulation element. The method further includes implementing the desired phase change to the portion of the radiation beam when applying the pattern feature to the substrate, the implementation of the desired phase change comprising illuminating the phase modulation element with the portion of the radiation beam when the phase modulation element is in the desired configuration.

Abstract: A fluid handling structure for a lithographic apparatus is disclosed. The fluid handling structure has, on an undersurface, a liquid supply opening or a plurality of liquid supply openings and a liquid extraction opening or a plurality of liquid extraction openings arranged such that, in use, liquid is provided on and removed from the undersurface of the fluid handling structure.

Abstract: Systems, methods, and apparatus are provided for determining overlay of a pattern on a substrate with a mask pattern defined in a resist layer on top of the pattern on the substrate. A first grating is provided under a second grating, each having substantially identical pitch to the other, together forming a composite grating. A first illumination beam is provided under an angle of incidence along a first horizontal direction. The intensity of a diffracted beam from the composite grating is measured. A second illumination beam is provided under the angle of incidence along a second horizontal direction. The second horizontal direction is opposite to the first horizontal direction. The intensity of the diffracted beam from the composite grating is measured. The difference between the diffracted beam from the first illumination beam and the diffracted beam from the second illumination beam, linearly scaled, results in the overlay error.

Abstract: A lithographic apparatus having a programmable patterning device and a projection system. The programmable patterning device is configured to provide a plurality of radiation beams. The projection system has a lens group array configured to project the plurality of radiation beams onto a substrate. The projection system further includes a focus adjuster in an optical path corresponding to a lens group of the lens group array. The focus adjuster has an optical element having substantially zero optical power.

Abstract: A three-dimensional mask model of the invention provides a more realistic approximation of the three-dimensional effects of a photolithography mask with sub-wavelength features than a thin-mask model. In one embodiment, the three-dimensional mask model includes a set of filtering kernels in the spatial domain that are configured to be convolved with thin-mask transmission functions to produce a near-field image. In another embodiment, the three-dimensional mask model includes a set of correction factors in the frequency domain that are configured to be multiplied by the Fourier transform of thin-mask transmission functions to produce a near-field image.

Abstract: A system and method of manufacturing a semiconductor device lithographically and an article of manufacture involving a lithographic double patterning process having a dye added to either the first or second lithographic pattern are provided. The dye is used to detect the location of the first lithographic pattern and to directly align the second lithographic pattern to it. The dye may be fluorescent, luminescent, absorbent, or reflective at a specified wavelength or a given wavelength band. The wavelength may correspond to the wavelength of an alignment beam. The dye allows for detection of the first lithographic pattern even when it is over coated with a radiation sensitive-layer (e.g., resist).

Abstract: An inspection apparatus for measuring a property of a substrate (W), includes a base frame, a substrate table (51) to hold the substrate, an illumination system arranged to direct a beam of radiation onto the substrate and a sensor arranged to detect radiation reflected off the substrate. Two balanced positioning systems displace the substrate table and sensor relative to the base frame in several directions. Each balanced positioning system includes a balance mass (59, 61), a bearing arrangement (65) to movably support the balance mass and tracks effective to guide the displacement in each direction. A motor arrangement causes the displacement in each direction. The balance mass is positioned relative to the track arrangement such that the centers of gravity of each balance mass and the substrate table or the sensor are substantially aligned in the direction substantially perpendicular to the plane including the direction of displacement.

Abstract: A method according to an embodiment includes obtaining calibration measurement data, with an optical detection apparatus, from a plurality of marker structure sets provided on a calibration substrate. Each marker structure set includes at least one calibration marker structure created using different known values of the process parameter. The method includes obtaining measurement data, with the optical detection apparatus, from at least one marker structure provided on a substrate and exposed using an unknown value of the process parameter; and determining the unknown value of the process parameter from the obtained measurement data by employing regression coefficients in a model based on the known values of the process parameter and the calibration measurement data.

Abstract: A lithographic apparatus includes at least one image alignment sensor for receiving radiation projected from an alignment mark on a reticle. Processor processes signals from the sensor(s) to resolve spatial information in the projected alignment mark to establish a reference for measuring positional relationships between a substrate support and the patterning location. Examples of the sensor include line arrays of photodetectors. A single array can resolve spatial information in a plane of the sensor (X, Y direction) and in a perpendicular (Z) direction. At least a final step in establishing the reference position is performed while holding the substrate support stationary. Errors and delays induced by mechanical scanning of prior art sensors are avoided. Alternatively (not illustrated) the sensor is moved for mechanical scanning relative to the substrate support, independently of the main positioning systems.

Abstract: A leaf spring to be mounted between two objects, the leaf spring configured to have a high stiffness in two orthogonal directions, and a relative low stiffness in other degrees of freedom, wherein the leaf spring has a substantially panel-shaped body, the leaf spring including a first mounting location at or near the center of the panel-shaped body to mount the leaf spring to a first of the two objects, wherein the leaf spring includes one or more second mounting locations at or near the circumference of the panel-shaped body to mount the leaf spring to the second of the two objects, and elongate grooves and/or slits in the panel shaped body between the first mounting location and the second mounting location, the grooves and/or slits running in at least two non-orthogonal directions in the plane of the two orthogonal directions.

Abstract: A liquid supply system for an immersion lithographic projection apparatus is disclosed in which a space is defined between the projection system, a barrier member and a substrate. The barrier member is not sealed such that, during use, immersion liquid is allowed to flow out the space and between the barrier member and the substrate.

Abstract: In order to improve overlay measurement, product marker gratings on a substrate are measured in a lithographic apparatus by an alignment sensor using scatterometry. Then information relating to the transverse profile of the product marker grating, such as its asymmetry, is determined from the measurement. After printing an overlay marker grating on a resist film, the lateral overlay of the overlay marker grating with respect to the product marker grating is measured by scatterometry and using the determined asymmetry information in combination with a suitable process model. The alignment sensor data may be used to first reconstruct the product grating and this information is fed forward to the scatterometer that measures the stack of product and resist grating and light scattered by the stack is used for reconstruction of a model of the stack to calculate overlay. The overlay may then, optionally, be fed back to the lithographic apparatus for correction of overlay errors.

Abstract: A lithographic apparatus including a fluid handling structure configured to contain immersion fluid in a space adjacent to an upper surface of the substrate table and/or a substrate located in a recess of the substrate table, a cover having a planar main body that, in use, extends around a substrate from the upper surface to a peripheral section of an upper major face of the substrate in order to cover a gap between an edge of the recess and an edge of the substrate, and an immersion fluid film disruptor, configured to disrupt the formation of a film of immersion fluid between an edge of the cover and immersion fluid contained by the fluid handling structure during movement of the substrate table relative to the fluid handling structure.

Abstract: A method to align a discharge axis of a discharge radiation source with respect to optics of the lithographic apparatus includes creating a discharge in a substance in a discharge space between an anode and a cathode to form a plasma so as to generate electromagnetic radiation. The discharge is triggered by irradiating an area on a surface proximate the discharge space with an energetic beam. The position of the area is controlled in response to a property of the radiation in the lithographic apparatus and/or the temperature of a collector of the lithographic apparatus. Controlling the position of the area which is irradiated improves alignment of the discharge axis with the different lithographic modules, such as the contamination barrier, the illumination system, the substrate table and/or the projection system.