Abstract: A charged particle system generates a charged particle multi beam along a multi beam path. The charged particle system comprises an aperture array, a beam limit array and a condenser lens. In the aperture array are an array of apertures to generate from an up-beam charged particle source charged particle paths down-beam of the aperture array. The beam-limit array is down-beam of the aperture array. Defined in the beam-limit array is an array of beam-limit apertures for shaping the charged particle multi beam path. The condenser lens system is between the aperture array and the beam-limit array. The condenser lens system selectively operates different of rotation settings that define different ranges of beam paths between the aperture array and the beam-limit array. At each rotation setting of the condenser lens system, each beam-limit aperture of the beam-limit array lies on a beam path down-beam of the aperture array.

Abstract: A method for generating metrology sampling scheme for a patterning process, the method including: obtaining a parameter map of a parameter of a patterning process for a substrate; decomposing the parameter map to generate a fingerprint specific to an apparatus of the patterning process and/or a combination of apparatuses of the patterning process; and based on the fingerprint, generating a metrology sampling scheme for a subsequent substrate at the apparatus of the patterning process and/or the combination of apparatuses of the patterning process, wherein the sampling scheme is configured to distribute sampling points on the subsequent substrate so as to improve a metrology sampling density.

Abstract: An imprint lithography apparatus having a first frame to be mounted on a floor, a second frame mounted on the first frame via a kinematic coupling, an alignment sensor mounted on the second frame, to align an imprint lithography template arrangement with a target portion of a substrate, and a position sensor to measure a position of the imprint lithography template arrangement and/or a substrate stage relative to the second frame.

Abstract: An assembly for collimating broadband radiation, the assembly including: a convex refractive singlet lens having a first spherical surface for coupling the broadband radiation into the lens and a second spherical surface for coupling the broadband radiation out of the lens, wherein the first and second spherical surfaces have a common center; and a mount for holding the convex refractive singlet lens at a plurality of contact points having a centroid coinciding with the common center.

Abstract: Multilayered product structures are formed on substrates by a combination of patterning steps, physical processing steps and chemical processing steps. An inspection apparatus illuminates a plurality of target structures and captures pupil images representing the angular distribution of radiation scattered by each target structure. The target structures have the same design but are formed at different locations on a substrate and/or on different substrates. Based on a comparison of the images the inspection apparatus infers the presence of process-induced stack variations between the different locations. In one application, the inspection apparatus separately measures overlay performance of the manufacturing process based on dark-field images, combined with previously determined calibration information. The calibration is adjusted for each target, depending on the stack variations inferred from the pupil images.

Abstract: A metrology system includes a radiation source, first, second, and third optical systems, and a processor. The first optical system splits the radiation into first and second beams of radiation and impart one or more phase differences between the first and second beams. The second optical system directs the first and second beams toward a target structure to produce first and second scattered beams of radiation. The third optical system interferes the first and second scattered beams at an imaging detector. The imaging detector generates a detection signal based on the interfered first and second scattered beams. The metrology system modulates one or more phase differences of the first and second scattered beams based on the imparted one or more phase differences. The processor analyzes the detection signal to determine a property of the target structure based on at least the modulated one or more phase differences.

Abstract: A method for manufacturing a membrane assembly for EUV lithography, the method including: providing a stack having a planar substrate and at least one membrane layer, wherein the planar substrate includes an inner region and a border region around the inner region; and selectively removing the inner region of the planar substrate. The membrane assembly includes: a membrane formed from the at least one membrane layer; and a border holding the membrane, the border formed from the border region of the planar substrate. The stack is provided with a mechanical protection material configured to mechanically protect the border region during the selectively removing the inner region of the planar substrate.

Abstract: A system includes an illumination system, an optical element, a switching element and a detector. The illumination system includes a broadband light source that generates a beam of radiation. The dispersive optical element receives the beam of radiation and generates a plurality of light beams having a narrower bandwidth than the broadband light source. The optical switch receives the plurality of light 5 beams and transmits each one of the plurality of light beams to a respective one of a plurality of alignment sensor of a sensor array. The detector receives radiation returning from the sensor array and to generate a measurement signal based on the received radiation.

Abstract: A detector includes a plurality of sensing elements, section circuitry that communicatively couples a first set of sensing elements to an input of first signal processing circuitry, and a switch network that connects sets of sensing elements. Inter-element switches may connect adjacent sensing elements, including those in a diagonal direction. An output bus may be connected to each sensing element of the first set by a switching element. There may be a common output (pickup point) arranged at one sensing element that is configured to output signals from the first set. Various switching and wiring schemes are proposed. For example, the common output may be directly connected to the switch network. A switch may be provided between the output bus and first signal processing circuitry. A switch may be provided between the switch network and the first signal processing circuitry.

Abstract: The present disclosure relates to a stage apparatus comprising: an object table configured to hold a substrate, the object table comprising an electrode configured to be charged by a power source and an electrical connection configured to electrically connect the electrode to the power source, and an electric field shield configured to shield at least a part of the electrical connection.

Abstract: An improved method and apparatus for enhancing an inspection image in a charged-particle beam inspection system. An improved method for enhancing an inspection image comprises acquiring a first image and a second image of multiple stacked layers of a sample that are taken with a first focal point and a second focal point, respectively, associating a first segment of the first image with a first layer among the multiple stacked layers and associating a second segment of the second image with a second layer among the multiple stacked layers, updating the first segment based on a first reference image corresponding to the first layer and updating the second segment based on a second reference image corresponding to the second layer, and combining the updated first segment and the updated second segment to generate a combined image including the first layer and the second layer.

Abstract: A reflector comprising a hollow body having an interior surface defining a passage through the hollow body, the interior surface having at least one optical surface part configured to reflect radiation and a supporter surface part, wherein the optical surface part has a predetermined optical power and the supporter surface part does not have the predetermined optical power. The reflector is made by providing an axially symmetric mandrel; shaping a part of the circumferential surface of the mandrel to form at least one inverse optical surface part that is not rotationally symmetric about the axis of the mandrel; forming a reflector body around the mandrel; and releasing the reflector body from the mandrel whereby the reflector body has an optical surface defined by the inverse optical surface part and a supporter surface part defined by the rest of the outer surface of the mandrel.

Abstract: A method of inspection for defects on a substrate, such as a reflective reticle substrate, and associated apparatuses. The method includes performing the inspection using inspection radiation obtained from a high harmonic generation source and having one or more wavelengths within a wavelength range of between 20 nm and 150 nm. Also, a method including performing a coarse inspection using first inspection radiation having one or more first wavelengths within a first wavelength range; and performing a fine inspection using second inspection radiation having one or more second wavelengths within a second wavelength range, the second wavelength range comprising wavelengths shorter than the first wavelength range.

Abstract: An apparatus for use in a metrology process or a lithographic process, the apparatus including: an object support module adapted to hold an object; and a first gas shower arranged on a first side of the object support module and adapted to emit a gas with a first velocity in a first gas direction which is a horizontal direction to cause a net gas flow in the apparatus to be a substantially horizontal gas flow in the first gas direction at least above the object support module.

Abstract: The invention provides a magnet assembly for a planar electromagnetic motor, the magnet assembly comprising:—a first plurality of superconductive (SC) coils, inside an outer circumference and arranged in a planar pattern such as a rectangular pattern,—a second plurality of SC coils, arranged along an outer boundary of the planar pattern, a coil of the first plurality of SC coils having a first in-plane shape and a coil of the second plurality of SC coils having a second in-plane shape, different from the first in-plane shape, wherein the second plurality of SC coils is arranged at least partly inside the outer circumference.

Abstract: The present invention concerns a method of determining alignment of electron optical components in a charged particle apparatus. The charged particle apparatus comprising: an aperture array and a detector configured to detect charged particles corresponding to beamlets that pass through the corresponding apertures in the aperture array. The method comprises: scanning each beamlet in a plane of the aperture array over a portion of the aperture array in which a corresponding aperture of the aperture array is defined so that charged particles of each beamlet may pass through the corresponding aperture; detecting during the scan any charged particles corresponding to each beamlet that passes through the corresponding aperture; generating a detection pixel for each beamlet based on the detection of charged particles corresponding to each beamlet at intervals of the scan; and collecting information comprised in the detection pixel such as the intensity of charged particles.

Abstract: Scanner aberration impact modeling in a semiconductor manufacturing process, which may facilitate co-optimization of multiple scanners. Scanner aberration impact modeling may include executing a calibrated model and controlling a scanner based on output from the model. The model is configured to receive patterning system aberration data. The model is calibrated with patterning system aberration calibration data and corresponding patterning process impact calibration data. New patterning process impact data may be determined, based on the model, for the received patterning system aberration data. The model includes a hyperdimensional function configured to correlate the received patterning system aberration data with the new patterning process impact data.

Abstract: Electron-optical devices and associated methods are disclosed. In one arrangement, an electron-optical device projects a multi-beam of sub-beams of charged particles to a sample. A plurality of plates are provided in which are defined respective aperture arrays. The plates comprise an objective lens array configured to project the sub-beams towards the sample. The aperture arrays defined in at least two of the plates each have a geometrical characteristic configured to apply a perturbation to a corresponding target property of the sub-beams. A controller controls potentials applied to the plates having the geometrical characteristics such that the applied perturbations together substantially compensate for a variation in the target property over a range of a parameter of the device.

Abstract: Systems, apparatuses, and methods are provided for generating level data. An example method can include receiving first level data for a first region of a substrate. The first region can include a first subregion having a first surface level, and a second subregion having a second surface level. The example method can further include generating, based on the first level data, measurement control map data. The example method can further include generating, based on the measurement control map data, second level data for a second region of the substrate. The second region can include a plurality of third subregions each having a third surface level equal to about the first surface level, and, optionally, no region having a surface level equal to about the second surface level.

Abstract: Disclosed herein is an actuator arrangement comprising: a wall defining a cavity; a casing protruding from the wall and defining an interior in fluid communication with the cavity; an actuator comprising: a force imparter configured to impart force on a component in the cavity; and an actuation mechanism configured to drive the force imparter, wherein at least part of the actuation mechanism is within said interior of the casing and exposed to the cavity; and a control element configured to control the actuation mechanism, wherein the control element extends through the casing via a seal.