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: An apparatus configured to handle an object in a contactless manner, the apparatus includes a carrying body having a carrying surface which is configured to be directed towards the object, the carrying surface being provided with a plurality of traction members and a plurality of overpressure members, each overpressure member being provided with at least one exhaust opening, each traction member being provided with an indentation and at least two suction openings that are arranged in the indentation, the at least two suction openings of each traction member being configured to generate a pressure gradient between them so as to create a traction fluid flow in the indentation in a direction substantially parallel to the carrying surface; and a pressure controller configured to control the pressure gradient between the at least two suction openings of each traction member.

Abstract: In an immersion lithographic apparatus, bubble formation in immersion liquid is reduced or prevented by reducing a gap size or area on a substrate table. The gap size is reduced using an edge member which may be, for example, a ring known as a BES (Bubble Extraction System) ring. Information regarding the shape and/or cross-sectional dimension (e.g., diameter) of the substrate, or information regarding the size of the gap, is transmitted to a controller that controls the edge member in order for the edge member, for example, to be reduced to an appropriate size to reduce the gap as much as possible, desirably without compressing the edge of the substrate. Alternatively or additionally, the gap may be reduced by moving the substrate and/or edge member adjacent the edge of a surface of the substrate table.

Abstract: A method for damping an object in two or more degrees of freedom, including measuring a position quantity at each of the two or more measurement locations; extracting from the measured position quantities a measurement signal for each dynamic mode; feeding the measurement signal of a dynamic mode to a controller unit associated with the respective dynamic mode, the controller unit providing for each dynamic mode an output signal on the basis of the respective measurement signal; and providing a control signal to each of the two or more actuators, the control signal for each actuator being based on output signals of one or more controller units.

Abstract: A level sensor configured to measure a height level of a substrate arranged in a measurement position is disclosed. The level sensor comprises a projection unit to project multiple measurement beams on multiple measurement locations on the substrate, a detection unit to receive the measurement beams after reflection on the substrate, and a processing unit to calculate a height level on the basis of the reflected measurement beams received by the detection unit, wherein the projection unit and the detection unit are arranged next to the substrate, when the substrate is arranged in the measurement position.

Abstract: A fluid handling structure is provided for a lithographic apparatus having at a boundary between a space containing immersion fluid and a region external to the fluid handling structure, a plurality of openings arranged in a first line, a first gas knife device having an aperture in a second line, one or more openings in a third line and a second gas knife device having an aperture in a fourth line.

Abstract: A robot positions a workpiece within a vacuum chamber of a lithographic apparatus. A first component of the robot is located within a vacuum chamber to position a workpiece along a translational axis. A shaft supports the first component such that an axis of symmetry of the shaft is perpendicular to the translational axis, and a second component rotates the shaft about the axis of symmetry and moves the shaft in a direction parallel to the axis of symmetry. The second component includes a gas bearing configured to introduce gas along a circumferential surface of the shaft and a scavenging seal configured to evacuate the gas introduced by the second component gas bearing. The robot substantially reduces, or eliminates the out-gassing of hydrocarbon molecules in a range from about 0 to 200 a.m.u., thus rendering the robot suitable for use in extreme ultra-violet (EUV) photolithography applications.

Abstract: An encoder-type measurement system is configured to measure a position dependent signal of a movable object. The measurement system includes a light source and a sensor. The light source and the sensor are mounted on one of the movable object or a substantially stationary frame. The measurement system also includes a reference object that includes a grating or grid mounted on the other of the movable object or the substantially stationary frame. The light source is configured to emit a light beam towards the reference object. The sensor is configured to detect light of the light source reflected by the reference object. The measurement system also includes an error detector capable of detecting errors in or on the grating or grid of the sensor target object during a continuous production process.

Abstract: A radiation spot measurement system for a lithographic apparatus, the system having a target onto which a radiation system of the lithographic apparatus may project spots of radiation for a measurement process, the target having a measurement target. The system further includes a radiation detector to detect radiation from one of the spots, and a controller to receive information from the radiation detector and to determine the position of the spot of radiation relative to an intended position of the spot of radiation.

Abstract: A lithographic apparatus includes a support constructed to support a patterning device, the patterning device being capable of imparting a radiation beam with a pattern in its cross-section to form a patterned radiation beam; a substrate table constructed to hold a substrate; a projection system configured to project the patterned radiation beam onto a target portion of the substrate; a sensor array positioned and arranged to detect an acoustic wave from a movable part of the lithographic apparatus, a controller, the controller having a controller input connected to the sensor array so as to receive a sensor array output signal, and a controller output connected to at least one actuator arranged to act on the movable part, the controller being arranged to: calculate a movement of the movable part from the sensor array output signal, and drive via the controller output the at least one actuator in response to the calculated movement.

Abstract: Variables in each step in a double patterning lithographic process are recorded and characteristics of intermediate features in a double patterning process measured. The final feature is then modeled, and the values of the variables optimized.

Abstract: Methods, computer program products and apparatuses for optimizing design rules for producing a mask are disclosed, while keeping the optical conditions (including but not limited to illumination shape, projection optics numerical aperture (NA) etc.) fixed. A cross-correlation function is created by multiplying the diffraction order functions of the mask patterns with the eigenfunctions from singular value decomposition (SVD) of a TCC matrix. The diffraction order functions are calculated for the original design rule set, i.e., using the unperturbed condition. ILS is calculated at an edge of a calculated image of a critical polygon using the cross-correlation results and using translation properties of a Fourier transform. The use of the calculated cross-correlation of the mask and the optical system, and the translation property of the Fourier transform for perturbing the design reduces the computation time needed for determining required changes in the design rules.

Abstract: A self-referencing interferometer includes an optical system to split an alignment beam to create a reference beam and a transformed beam. The optical system includes a beam splitter to combine the reference beam and the transformed beam so that the diffraction orders in the reference beam spatially overlap with their respective opposite orders in the transformed beam. A detector system receives the spatially overlapping reference beam and transformed beam from the optical system and determines a position signal. The detector system includes a polarizing system for manipulating the polarization of the beams so that they interfere, and for directing the interfering reference beam and transformed beam to a detector for determining a position signal from the variation of intensity of the interfering beams.

Abstract: A conditioning system for conditioning a part of a lithographic apparatus, includes an evaporator positioned in thermal contact with the part for extracting heat from the part by evaporation of a fluid inside the evaporator; a condenser for removing heat from the fluid inside the condenser; fluid lines arranged between the evaporator and the condenser to form a fluid circuit; a pump arranged in the circuit to circulate the fluid in the circuit; an accumulator to hold fluid, wherein the accumulator is in fluid communication with the circuit and comprises a heat exchanger to transfer heat from or to fluid inside the accumulator; a temperature sensor to provide a signal representative of the fluid temperature; and a controller to maintain a substantially constant temperature of the fluid inside the circuit by regulating the amount of heat transferred by the heat exchanger based on the signal.

Abstract: A substrate comprises a first mark and a second mark. The first mark comprises a first pattern with at least one mark feature formed by a first material and at least one region formed by a second material. The first and second materials have different material characteristics with respect to a substrate treatment process such that a step height in a direction substantially perpendicular to the surface of the substrate may be created by applying the substrate treatment process. The second mark can be provided with a second step height by applying the substrate treatment process. The second step height is substantially different from the first step height.

Abstract: A lithographic apparatus includes an illumination system configured to provide a first beam of radiation, which forms a first mask illumination region, and configured to substantially simultaneously provide a second beam of radiation, which forms a second mask illumination region. The first and second illumination regions being configured to substantially simultaneously illuminate a same mask. The lithographic apparatus also includes a projection system configured to project the first radiation beam such that it forms a first substrate illumination region and configured to simultaneously project the second radiation beam such that it forms a second substrate illumination region.

Abstract: A radiation source is configured to produce extreme ultraviolet radiation. The radiation source includes a chamber in which, in use, a plasma is generated, and an evaporation surface configured to evaporate a material formed as a by-product from the plasma and that is emitted to the evaporation surface. A method for removing a by-product material in or from a plasma radiation source of a lithographic apparatus includes evaporating a material which, in use, is emitted to that surface from the plasma.

Abstract: In one aspect, the present invention is directed to a technique of, and system for simulating, verifying, inspecting, characterizing, determining and/or evaluating the lithographic designs, techniques and/or systems, and/or individual functions performed thereby or components used therein. In one embodiment, the present invention is a system and method that accelerates lithography simulation, inspection, characterization and/or evaluation of the optical characteristics and/or properties, as well as the effects and/or interactions of lithographic systems and processing techniques.

Abstract: Described herein is a method for a lithographic process for imaging a portion of a design layout onto a substrate using a lithographic imaging apparatus, the lithographic process having a plurality of design variables, the method comprising: calculating a gradient of each of a plurality of evaluation points or patterns of the lithographic process, with respect to at least one of the design variables; and selecting a subset of evaluation points from the plurality of evaluation points or patterns based on the gradient.

Abstract: A substrate support is provided for a lithographic apparatus. The support comprises a substrate table constructed to hold a substrate and a chuck for the substrate table. In operation, the substrate table is supported by the chuck and clamped thereto. The substrate support comprises a first set of burls on a surface of the support block for abutting against the substrate table during the clamping and a second set of burls on a surface of the substrate table for abutting against the support block during the clamping.