Abstract: An absorptive grid polarization element includes a transparent substrate, and a stripe-like grid provided on the transparent substrate. Each of a plurality of linear parts which form the grid absorbs more s polarization light than p polarization light, and thus achieves a polarizing action. The transparent substrate is made of quartz glass. Each of the linear parts includes a second layer formed on the transparent substrate, and a first layer formed on the second layer. The first layers are formed from amorphous titanium oxide. The second layers are formed from amorphous silicon.

Abstract: An object table to support an object, the object table having a support body, an object holder to hold an object, an opening adjacent an edge of the object holder, and a channel in fluid communication with the opening via a passageway, wherein the channel is defined by a first material which is different to a second material defining the passageway.

Abstract: A liquid immersion member including first and second members forming the immersion space; first member having a first lower surface disposed at a portion of the optical member surrounding, second member having a second upper surface opposite to the first lower surface via a gap and a second lower surface opposing the substrate and second member disposed at a portion of exposure light optical path surrounding; driving apparatus to move the second member with respect to the first; controlling the driving apparatus so the second member's operation in the substrate first operation movement is between exposure termination and start of a first and second shot regions differently from a second member's operation in the substrate second movement period which is between exposure termination and start of a third and fourth shot regions; first and second shot regions are in the same row contrary to third and fourth shot regions.

Abstract: An exposure apparatus obtains information on a relationship between a moving amount of a substrate stage in the first direction and an amount of a positional shift in an image of a mask-side reference mark projected on a substrate-side reference mark by a projection optical system in the second direction perpendicular to an optical axis of the projection optical system with respect to the substrate-side reference mark. A controller determines a focus position based on the measurement result by causing the measurement device to measure the light amount while, together with driving the substrate stage in the first direction and the second direction based on the information.

Abstract: A substrate liquid treatment method includes: (a) rotating the substrate about the vertical axis; (b) supplying the treatment liquid to the rotating substrate from the second nozzle with a falling point of the treatment liquid supplied from the second nozzle moving from the central portion to the peripheral portion of the substrate, while supplying the treatment liquid to the central portion of the substrate from the first nozzle, (c) after (b), moving the second nozzle from the peripheral portion to the central portion of the substrate with the supplying of the treatment liquid from the second nozzle being stopped, while continuing supplying the treatment liquid to the central portion of the rotating substrate from the first nozzle; and (d) after (c), supplying the treatment liquid to the rotating substrate from the second nozzle.

Abstract: Microlithographic illumination system includes individually drivable elements to variably illuminate a pupil surface of the system. Each element deviates an incident light beam based on a control signal applied to the element. The system also includes an instrument to provide a measurement signal, and a model-based state estimator configured to compute, for each element, an estimated state vector based on the measurement signal. The estimated state vector represents: a deviation of a light beam caused by the element; and a time derivative of the deviation. The illumination system further includes a regulator configured to receive, for each element: a) the estimated state vector; and b) target values for: i) the deviation of the light beam caused by the deviating element; and ii) the time derivative of the deviation.

Abstract: A system and method is provided for providing a thermal distribution on a workpiece during a lithographic process. The system provides a source of lithographic energy to workpiece, such as a workpiece having a lithographic film formed thereover. A workpiece support having a plurality of thermal devices embedded therein is configured to support the workpiece concurrent to an exposure of the workpiece to the lithographic energy. A controller individually controls a temperature of each of the plurality of thermal devices, therein controlling a specified temperature distribution across the workpiece associated with the exposure of the workpiece to the lithographic energy. Controlling the temperature of the thermal devices can be based on a model, a measured temperature of the workpiece, and/or a prediction of a temperature at one or more locations on the workpiece.

Abstract: A stage positioning system, includes a first body, a second body and a coupling arranged to couple the first body and the second body to each other. The coupling includes a visco-elastic element arranged to couple the first body and the second body to each other. The stage positioning system may further include a sensor to provide a signal representative of a position of the first body. The stage positioning system may further include an actuator to move the first body. The second body may be arranged to couple the actuator and the coupling to each other.

Abstract: A lithographic apparatus includes a substrate table constructed to hold a substrate; a compartment configured to receive the substrate table; a thermal conditioning unit arranged to receive a substrate to be exposed and thermally condition the substrate; and a transfer system for transferring a thermally conditioned substrate to the substrate table, wherein the substrate table and the thermal conditioning unit are arranged inside the compartment of the lithographic apparatus, at least during a transfer of the thermally conditioned substrate from the thermal conditioning unit to the substrate table.

Abstract: Disclosed is a method of measuring a parameter of a lithographic process, and associated computer program and apparatuses. The method comprises providing a plurality of target structures on a substrate, each target structure comprising a first structure and a second structure on different layers of the substrate. Each target structure is measured with measurement radiation to obtain a measurement of target asymmetry in the target structure, the target asymmetry comprising an overlay contribution due to misalignment of the first and second structures, and a structural contribution due to structural asymmetry in at least the first structure. A structural asymmetry characteristic relating to the structural asymmetry in at least the first structure of each target structure is obtained, the structural asymmetry characteristic being independent of at least one selected characteristic of the measurement radiation.

Abstract: A mirror array includes a multiplicity of displaceable individual mirrors which are subdivided into at least two groups. The individual mirrors of the first group are displaceable in a very precise manner, and the individual mirrors of the second group are displaceable in a very quick manner.

Abstract: The invention relates to a method for regulating a light source of a photolithography exposure system which comprises a plurality of LEDs, by means of the following steps: the light output of the individual LEDs in specific wavelength ranges is detected, and the detected light output is compared with a desired light output distribution over the entire spectrum. The LEDs are operated such that the desired spectral light output distribution is achieved in the most precise manner possible. The invention also relates to an exposure assembly for a photolithography device, having a light source which comprises a plurality of LEDs, a control means which controls the electrical power supplied to the individual LEDs, and a sensor which can detect the light output of the LEDs in the respective ranges of the wavelengths.

Abstract: A wafer holding apparatus for holding a wafer including a wafer holder on which the wafer is placed; and a lift pin that is configured to be lifted up and down with respect to the wafer holder in a direction along a normal line of a placement surface of the wafer, the lift pin includes a tip part, the tip part includes: a bottom part that forms a suction region for sucking a rear surface of the wafer; and a convex part that supports the rear surface of the wafer in the suction region. When a substrate is placed on a target position, it is possible to prevent a local deterioration of flatness of the substrate even if the substrate is large.

Abstract: A method for fabricating a pattern on a semiconductor substrate, comprising the steps of: (a) providing the semiconductor substrate having a photosensitive layer thereon; (b) transmitting the semiconductor substrate to an exposure apparatus including several tubes; (c) providing the supporting assembly to support the tubes, where the supporting assembly includes a first supporting rod having several first parallel recesses, a second supporting rod disposed opposite to the first supporting rod, a bridging member connected to one end of the first supporting rod or one end of the second supporting rod; and a rolling member received by the bridging member; (d) providing a photomask to the exposure apparatus; and (e) transferring the pattern from the photomask to the photosensitive layer.

Abstract: An exposure apparatus includes a liquid immersion member including a first member and a second member and configured to form a liquid immersion space of the liquid, a driving apparatus configured to move the second member with respect to the first member; and a controller configured to control the driving apparatus. The controller controls the driving apparatus so that a first operation of the second member in a first movement period of the substrate between exposure termination of a first shot region and exposure start of a second shot region is different from a second operation of the second member in a second movement period of the substrate between exposure termination of a third shot region and exposure start of a fourth shot region, the first and second shot regions being included in the same row, the third and fourth shot regions being arranged in different rows.

Abstract: A table for a lithographic apparatus, the table having a catchment opening formed in an upper surface of the table, the catchment opening in fluid communication through the table with the environment of the table at a drain opening in a surface of the table other than the upper surface.

Abstract: A method and apparatus for optical metrology is disclosed. There is disclosed, for example, a method involving a radiation intensity distribution for a target measured using an optical component at a gap from the target, the method including calculating a correction factor for the variation of radiation intensity of the radiation intensity distribution as a function of variation of the distance of the gap.

Abstract: A substrate is exposed with an illumination light via a projection optical system. A stage that holds the substrate moves below the projection optical system. A measurement system measures positional information of the stage with a plurality of heads that face a grating section. Movement of the stage is controlled based on the positional information measured with the measurement system, while compensating for a measurement error of the measurement system that occurs due to the heads.

Abstract: The invention relates to arrangements for actuating an element in a microlithographic projection exposure apparatus. In accordance with one aspect, an arrangement for actuating an element in a microlithographic projection exposure apparatus comprises a first number (nR) of degrees of freedom, wherein an adjustable force can be transmitted to the optical element in each of the degrees of freedom, and a second number (nA) of actuators, which are coupled to the optical element in each case via a mechanical coupling for the purpose of transmitting force to the optical element, wherein the second number (nA) is greater than the first number (nR). In accordance with one aspect, at least one of the actuators is arranged in a node of at least one natural vibration mode of the optical element.

Abstract: A faceted reflector (32, 32?) for receiving an incident radiation beam (2) and directing a reflected radiation beam at a target. The faceted reflector comprises a plurality of facets, each of the plurality of facets comprising a reflective surface. The reflective surfaces of each of a first subset of the plurality of facets define respective parts of a first continuous surface and are arranged to reflect respective first portions of the incident radiation beam in a first direction to provide a first portion of the reflected radiation beam. The reflective surfaces of each of a second subset of the plurality of facets define respective parts of a second continuous surface and are arranged to reflect respective second portions of the incident radiation beam in a second direction to provide a second portion of the reflected radiation beam.