Abstract: A vacuum system for extracting a stream of a multi-phase fluid from a photolithography tool comprises a pumping arrangement for drawing the fluid from the tool, and an extraction tank located upstream from the pumping arrangement for separating the fluid drawn from the tool into gas and liquid phases. The pumping arrangement comprises a first pump for extracting gas from the tank, and a second pump for extracting liquid from the tank. In order to minimize any pressure fluctuations transmitted from the vacuum system back to the fluid within the tool, a pressure control system maintains a substantially constant pressure in the tank by regulating the amounts of liquid and gas within the tank.

Abstract: A patterning device carries a pattern of features to be transferred onto a substrate using a lithographic apparatus. The patterning device is free of light absorber material, at least in an area. The pattern of features in the area may include a dense array of lines, trenches, dots or holes. Individual lines, holes, etc. are defined in at least one direction by pairs of edges between regions of different phase in the patterning device. A distance between the pair of edges in the at least one direction is at least 15% smaller than a size of the individual feature to be formed on the substrate once adjusted by a magnification factor, if any, of the lithographic apparatus. The patterning device may be adapted for use in EUV lithography. The patterning device may be adapted for use in a negative tone resist and development process.

Abstract: Disclosed is a method of measuring overlay between upper and lower layers on a substrate using metrology targets formed by a lithographic process. The lithographic process is of a multiple-patterning type whereby first and second distinct populations of structures are formed in a single one of said layers (L1) by respective first and second patterning steps. The metrology target (620) in the single one of said layers comprises a set of structures of which different subsets (642A, 642B) are formed in said first and second patterning steps. An overlay measurement on this target can be used to calculate a combined (average) overlay performance parameter for both of the first and second patterning steps.

Abstract: Disclosed is a method of determining a correction for measured values of radiation diffracted from a target comprising a plurality of periodic structures, subsequent to measurement of the target using measurement radiation defining a measurement field. The correction acts to correct for measurement field location dependence in the measured values. The method comprises performing a first and second measurements of the periodic structures; and determining a correction from said first measurement and said second measurement. The first measurement is performed with said target being in a normal measurement location with respect to the measurement field. The second measurement is performed with the periodic structure in a shifted location with respect to the measurement field, said shifted location comprising the location of another of said periodic structures when said target is in said normal measurement location with respect to the measurement field.

Abstract: A lithographic reticle is illuminated to transfer a pattern to a substrate, inducing distortions due to heating. The distortions are calculated using reference marks in a peripheral portion of the reticle and measuring changes in their relative positions over time. A plurality of cells are defined for which a system of equations can be solved to calculate a dilation of each cell. In an embodiment, each equation relates positions of pairs of marks to dilations of the cells along a fine (s, s1, s2) connecting each pair. Local positional deviations can be calculated for a position by combining calculated dilations for cells between at least one measured peripheral mark and the position. Corrections can be applied in accordance with the result of the calculation. Energy may be applied to the patterning device (for example by thermal input or mechanical actuators) to modify a distribution of the local positional deviations.

Abstract: A method of exposing a patterned area on a substrate using an EUV lithographic apparatus having a demagnification of about 5× and a numerical aperture of about 0.4 is disclosed. The method comprises exposing a first portion of the patterned area on the substrate using a first exposure, the first portion dimensions are significantly less than the dimensions of a conventional exposure, and exposing one or more additional portions of the patterned area on the substrate using one or more additional exposures, the additional portions having dimensions which are significantly less than the dimensions of a conventional exposure. The method further comprises repeating the above to expose a second patterned area on the substrate, the second patterned area being provided with the same pattern as the first patterned area, wherein a distance between center points of the first and second patterned areas corresponds with a dimension of a conventional exposure.

Abstract: A lithographic apparatus having a reference body and a positioning system, the positioning system including a main body; a reaction body; an actuator; and a controller. The main body is moveable relative to the reference body along a path in a first direction and a second opposite direction. The reaction body is moveable relative to the main body along a further path in the first and second directions and is moveably connected to the reference body to be moveable relative to the reference body in the first and second directions. The controller provides a first and a second signal to the actuator. The actuator is arranged between the main body and the reaction body to accelerate the main body in the first direction and to accelerate the reaction body in the second direction under control of the first signal, and to accelerate the main body in the second direction and to accelerate the reaction body in the first direction under control of the second signal.

Abstract: A method of determining a position of an imprint template in an imprint lithography apparatus is disclosed. In an embodiment, the method includes illuminating an area of the imprint template in which an alignment mark is expected to be found by scanning an alignment radiation beam over that area, detecting an intensity of radiation reflected or transmitted from the area, and identifying the alignment mark via analysis of the detected intensity.

Abstract: Disclosed is an inspection apparatus for use in lithography. It comprises a support for a substrate carrying a plurality of metrology targets; an optical system for illuminating the targets under predetermined illumination conditions and for detecting predetermined portions of radiation diffracted by the targets under the illumination conditions; a processor arranged to calculate from said detected portions of diffracted radiation a measurement of asymmetry for a specific target; and a controller for causing the optical system and processor to measure asymmetry in at least two of said targets which have different known components of positional offset between structures and smaller sub-structures within a layer on the substrate and calculate from the results of said asymmetry measurements a measurement of a performance parameter of the lithographic process for structures of said smaller size. Also disclosed are substrates provided with a plurality of novel metrology targets formed by a lithographic process.

Abstract: An apparatus has a first component with a first surface and a second component with a second surface, wherein the first and second components can undergo relative movement. The first surface and the second surface face each other. The first surface accommodates a barrier system to provide a barrier to reduce or prevent an inflow of ambient gas into a protected volume of gas between the first and second surfaces. The barrier system includes a curtain opening adapted for a flow of curtain gas therefrom for establishing a gas curtain enclosing part of the protected volume, and an inner entrainment opening, located inward of the curtain opening with respect to the protected volume, adapted for a flow of inner entrainment gas therefrom for being entrained into the flow of curtain gas. The apparatus is configured such that the inner entrainment gas flow is less turbulent than the curtain gas flow.

Abstract: A lithographic apparatus with a cover plate formed separately from a substrate table and means for stabilizing a temperature of the substrate table by controlling the temperature of the cover plate is disclosed. A lithographic apparatus with thermal insulation provided between a cover plate and a substrate table so that the cover plate acts as a thermal shield for the substrate table is disclosed. A lithographic apparatus comprising means to determine a substrate table distortion and improve position control of a substrate by reference to the substrate table distortion is disclosed.

Abstract: An immersion lithography apparatus is disclosed in which liquid is supplied to a space between a projection system and a substrate, and a plate structure is provided to divide the space into two parts. The plate structure has an aperture to allow transmission of the projection beam, has through holes in it to reduce the damping effect of the presence of the plate and optionally has one or more inlets and outlets to provide various flows around the aperture in the plate. An embodiment of the invention may reduce the transportation of contaminants, stray light, temperature gradients, and/or the effect of bubbles on the imaging quality.

Abstract: A method of determining exposure dose of a lithographic apparatus used in a lithographic process on a substrate, the method comprising the steps: (a) receiving a substrate comprising first and second structures produced using the lithographic process; (b) detecting scattered radiation while illuminating the first structure with radiation to obtain a first scatterometer signal; (c) detecting scattered radiation while illuminating the second structure with radiation to obtain a second scatterometer signal; (d) using the first and second scatterometer signals to determine an exposure dose value used to produce said first and second structures wherein the first structure has a first periodic characteristic with spatial characteristics and yet at least another second periodic characteristic with spatial characteristics designed to be affected by the exposure dose and the second structure has a first periodic characteristic with spatial characteristics and yet at least another second periodic characteristic with sp

Abstract: The present disclosure relates to lithographic apparatuses and processes, and more particularly to tools for optimizing illumination sources and masks for use in lithographic apparatuses and processes. According to certain aspects, the present disclosure significantly speeds up the convergence of the optimization by allowing direct computation of gradient of the cost function. According to other aspects, the present disclosure allows for simultaneous optimization of both source and mask, thereby significantly speeding the overall convergence. According to still further aspects, the present disclosure allows for free-form optimization, without the constraints required by conventional optimization techniques.

Abstract: An immersion lithographic projection apparatus is disclosed in which liquid is provided between a projection system of the apparatus and a substrate. The use of both liquidphobic and liquidphilic layers on various elements of the apparatus is provided to help prevent formation of bubbles in the liquid and to help reduce residue on the elements after being in contact with the liquid.

Abstract: An undulator for a free electron laser includes a pipe for an electron beam and one or more periodic magnetic structures extending axially along the pipe. Each periodic magnetic structure includes a plurality of magnets and a plurality of passive ferromagnetic elements, the plurality of magnets being arranged alternately with the plurality of passive ferromagnetic elements in a line extending in an axial direction. Each of the plurality of magnets is spatially separated from the pipe, and each of the passive ferromagnetic elements extends radially from an adjacent magnet towards the pipe. A spacer element may be provided between the magnets and the pipe to provide radiation shielding for the magnets and/or cooling for the pipe.

Abstract: Disclosed are an inspection method and apparatus and an associated lithographic apparatus. The inspection method comprises illuminating a structure with inspection radiation of a selected wavelength, the structure being of a type comprising a plurality of layers (for example a 3D memory structure). The resultant diffraction signal is detected a physical property of a subset of said layers is determined from said diffraction signal. The subset of layers for which said physical property is determined is dependent upon the selected wavelength of the inspection radiation.

Abstract: A method of determining a configuration of a projection system for a lithographic apparatus, wherein manipulators of the projection system manipulate optical elements so as to adjust its optical properties, the method comprising: receiving dependencies of the optical properties of the projection system on a configuration of the manipulators, receiving a plurality of constraints of the manipulators, formulating a cost function, wherein the cost function represents a difference between the optical properties of the projection system for a given configuration of the manipulators and desired optical properties, wherein the cost function is formulated using the dependency of the optical properties on the configuration of the manipulators, scaling the cost function into a scaled variable space, wherein the scaling is performed by using the plurality of constraints and finding a solution configuration of the manipulators which substantially minimises the scaled cost function subject to satisfying the plurality of co

Abstract: A support apparatus for a lithographic apparatus has an object holder and an extraction body radially outward of the object holder, The object holder is configured to support an object. The extraction body includes an extraction opening configured to extract fluid from a top surface of the support apparatus. The extraction body is spaced from the object holder such that the extraction body is substantially decoupled from the object holder.

Abstract: Metrology apparatus and methods are disclosed. In one arrangement, a substrate is inspected. A source beam of radiation emitted by a radiation source is split into a measurement beam and a reference beam. A first target is illuminated with the measurement beam, the first target being on the substrate. A second target is illuminated with the reference beam, the second target being separated from the substrate. First scattered radiation is collected from the first target and delivered to a detector. Second scattered radiation is collected from the second target and delivered to the detector. The first scattered radiation interferes with the second scattered radiation at the detector. The first target comprises a first pattern. The second target comprises a second pattern, or a pupil plane image of the second pattern.