Abstract: A method of efficient simulating imaging performance of a lithographic process utilized to image a target design having a plurality of features. The method includes the steps of determining a function for generating a simulated image, where the function accounts for process variations associated with the lithographic process; and generating the simulated image utilizing the function, where the simulated image represents the imaging result of the target design for the lithographic process.

Abstract: A movable stage system is configured to support an object. The stage system comprises an object table configured to support the object and an object table support defining an object table support surface configured to support the object table. The object table support comprises at least one first actuator to drive the object table support in a first driving direction substantially parallel to the object table support surface. In a projection on a plane parallel to the object table support surface the at least one actuator is spaced with respect to the object table in a direction perpendicular to the first driving direction such that the risk on slip between the object table support and the object table supported thereon is decreased.

Abstract: An imprint lithography apparatus is disclosed that includes an imprint template holder arranged to hold an imprint template, and a plurality of position sensors configured to measure change of the size and/or shape of the imprint template, wherein the position sensors are mechanically isolated from the imprint template. Also disclosed is a lithography method that includes using an imprint template to imprint a pattern onto a substrate, and measuring changes of the size and/or shape of the imprint template while imprinting the pattern onto the substrate.

Abstract: A radiation source includes a nozzle configured to direct a stream of fuel droplets along a droplet path towards a plasma formation location, and is configured to receive a gaussian radiation beam having gaussian intensity distribution, having a predetermined wavelength and propagating along a predetermined trajectory, and further configured to focus the radiation beam on a fuel droplet at the plasma formation location. The radiation source includes a phase plate structure including one or more phase plates. The phase plate structure has a first zone and a second zone. The zones are arranged such that radiation having the predetermined wavelength passing through the first zone and radiation having the predetermined wavelength passing through the second zone propagate along respective optical paths having different optical path lengths. A difference between the optical path lengths is an odd number of times half the predetermined wavelength.

Abstract: A lithographic apparatus and programmable patterning device is disclosed that includes a modulator configured to expose an exposure area of the substrate to a plurality of beams modulated according to a desired pattern and a projection system configured to project the modulated beams onto the substrate. The modulator includes a plurality of VECSELs or VCSELs. The projection system may include a zone plate array that is oscillated in a Lissajous pattern. The zone plate array may include lenses arranged in a two-dimensional array where the lenses are arranged in a triangular layout. A lithographic system may include a plurality of the lithographic apparatuses, at least one lithographic apparatus being arranged above another lithographic apparatus.

Abstract: An immersion lithographic apparatus is configured to subject a photosensitive layer on a substrate to a patterned beam of radiation via a liquid. The immersion lithographic apparatus includes a moveable object having a surface, a fluid handling system to control a presence of the liquid in a volume restricted by the surface, the fluid handling system, and a free surface of the liquid, the free surface extending between the surface and the fluid handling system; and a heating system configured to locally heat a portion of the liquid at a receding side of a periphery edge of the volume in contact with the surface, where the object is receding from the volume along a direction of movement of the object relative to the fluid handling system.

Abstract: An immersion lithography apparatus comprises a temperature controller configured to adjust a temperature of a projection system, a substrate and a liquid towards a common target temperature. Controlling the temperature of these elements and reducing temperature gradients may improve imaging consistency and general lithographic performance. Measures to control the temperature may include controlling the immersion liquid flow rate and liquid temperature, for example, via a feedback circuit.

Abstract: A fluid handling structure for a lithographic apparatus is disclosed. The fluid handling structure has a plurality of openings arranged in plan, in a line. The fluid handling structure is configured such that the openings are directed, in use, towards a facing surface, the facing surface being a substrate and/or a substrate table. The substrate table is configured to support the substrate. Outward of the line of openings is a damper. The damper may have a width that varies along the line of openings. The damper width is defined between the line of openings and an opposing damper edge.

Abstract: There is provided a positioning system for positioning an object in a lithographic apparatus. The positioning system includes a support, a position measurement device, a deformation sensor and a processor. The support is constructed to hold the object. The position measurement device is configured to measure a position of the support. The position measurement device includes at least one position sensor target and a plurality of position sensors to cooperate with the at least one position sensor target to provide a redundant set of position signals representing the position of the support. The deformation sensor is arranged to provide a deformation signal representing a deformation of one of the support and the position measurement device. The processor is configured to calibrate one of the position measurement device and the deformation sensor based on the deformation signal and the redundant set of position signals.

Abstract: A method of obtaining information indicative of the topography of a surface of a flexible substrate, the method including directing a beam of radiation at the surface of the flexible substrate; and detecting changes in intensity distribution, or angle of reflection, of the beam of radiation after the beam of radiation has been reflected from the surface of the substrate to obtain information indicative of the topography of the surface of the flexible substrate.

Abstract: A support table to support a surface of a substrate, wherein the support table includes: a base surface substantially parallel to the surface of the substrate, a plurality of burls protruding above the base surface, each of the burls having a respective distal end and a first height above the base surface, the burls arranged such that, when the substrate is supported by the support table, the substrate is supported by the respective distal ends, and a plurality of elongate raised protrusions separated by gaps, each of the elongate raised protrusions having a second height above the base surface, wherein the elongate raised protrusions protrude above the base surface between the burls, and the second height is less than the first height; wherein the protrusions are arranged such that a plurality of the gaps are aligned to form a straight gas flow path towards an edge of the base surface.

Abstract: An immersion lithographic apparatus includes a projection system, a first table with a first planar surface and a second table with a second planar surface, the first and second planar surfaces being substantially coplanar, a liquid confinement system configured to spatially confine an immersion liquid to a volume with a first surface area that is coplanar with the first and second planar surfaces, and is substantially smaller than a second surface area of the top surface of the substrate, and a swap bridge member attached to the first table, the swap bridge member having an upper surface that is substantially coplanar with the first and second planar surfaces, wherein the upper surface of the swap bridge member is configured to serve as part of the liquid confinement system and to deform when the swap bridge member collides with the second table and to remain attached to the first table.

Abstract: Described herein are methods for matching the characteristics of a lithographic projection apparatus to a reference lithographic projection apparatus, where the matching includes optimizing illumination source and projection optics characteristics. The projection optics can be used to shape wavefront in the lithographic projection apparatus. According to the embodiments herein, the methods can be accelerated by using linear fitting algorithm or using Taylor series expansion using partial derivatives of transmission cross coefficients (TCCs).

Abstract: A system for an extreme ultraviolet (EUV) light source includes an optical amplifier including a gain medium positioned on a beam path, the optical amplifier configured to receive a light beam at an input and to emit an output light beam for an EUV light source at an output; a feedback system that measures a property of the output light beam and produces a feedback signal based on the measured property; and an adaptive optic positioned in the beam path and configured to receive the feedback signal and to adjust a property of the output light beam in response to the feedback signal.

Abstract: Position and curvature information of a patterning device may be determined directly from the patterning device and controlled based on the determined information. In an embodiment, a lithographic apparatus includes a position determining system operative to determine a relative position of the patterning device. The patterning device may be configured to create a patterned radiation beam from a radiation beam incident on a major surface of the patterning device. The patterning device may have a side surface having an edge in common with the major surface. The position determining system may include an interferometer operative to transmit light to the side surface and to receive the transmitted light after the transmitted light has been reflected at the side surface. The position determining system is operative to determine a quantity representative of the relative position of the patterning device from the received reflected transmitted light.

Abstract: A lithographic apparatus is arranged to transfer a pattern from a patterning device onto a substrate. The lithographic apparatus includes an acoustical sensor to measure a first acoustic vibration in a sensor measurement area in the lithographic apparatus. An actuator is provided to generate a second acoustic vibration in at least an area of the lithographic apparatus. Further, a control device is provided having a sensor input to receive a sensor signal of the acoustical sensor and an actuator output to provide an actuator drive signal to the actuator. The control device is arranged to drive the actuator so as to let the second acoustic vibration at least partly compensate in the area the first acoustic vibration.

Abstract: A grazing incidence reflector (300) for EUV radiation includes a first mirror layer (310) and a multilayer mirror structure (320) beneath the first mirror layer. The first mirror layer reflects at least partially EUV radiation incident on the reflector with grazing incidence angles in a first range, and the first mirror layer transmits EUV radiation in a second range of incidence angles, which overlaps and extends beyond the first range of incidence angles. The multilayer mirror structure reflects EUV radiation that is incident on the reflector with grazing incidence angles in a second range that penetrates through the first mirror layer. A grazing incidence reflector can be used in a lithographic apparatus and in manufacturing a device by a lithographic process.

Abstract: A lithographic apparatus having a fluid handling structure configured to contain immersion fluid in a space adjacent to an upper surface of a substrate table and/or a substrate located in a recess of the substrate table, a cover including 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 of design or verification for a self-assemblable block copolymer feature, the block copolymer feature including a first domain having a first polymer type and a second domain having a second polymer type, the method including, based on the length of the second polymer type or on an uncertainty in position of the first domain within the block copolymer feature calculated based on the length of the second polymer type, adjusting a parameter of the self-assembly process of a block copolymer feature or verifying a placement of a block copolymer feature.

Abstract: A scatterometer is used in a dark-field imaging mode to measure asymmetry-related parameters such as overlay. Measurements of small grating targets are made using identical optical paths, with the target in two orientations to obtain separate measurements of +1 and ?1 diffraction orders. In this way, intensity scaling differences (tool asymmetry) are avoided. However, additive intensity defects due to stray radiation (ghosts) in the optical system cannot be avoided. Additive intensity issues strongly depend on the ratio between 0th and 1st order diffraction and are therefore strongly substrate (process) dependent. Calibration measurements are made on a few representative target gratings having biases. The calibration measurements are made, using not only different substrate rotations but also complementary apertures. Corrections are calculated and applied to correct asymmetry, to reduce error caused by stray radiation.