A stage assembly (10) that includes (i) a stage (14) that retains a device (26); (ii) a reaction assembly (18) that is spaced apart from the stage (14); (iii) a stage mover (16) that moves the stage (14), the stage mover (16) including a magnet array (38) that is coupled to the stage (14) and a conductor array (36) that is coupled to the reaction assembly (18); (iv) a temperature adjuster (20); and (v) a control system (22) that selectively controls the temperature adjuster (20). The conductor array (36) includes a set of first zone conductor units (250), and a set of second zone conductor units (252). The temperature adjuster (20) independently adjusts the temperature of the set of first zone conductor units (250), and the set of second zone conductor units (252).

An apparatus comprising at least one sealing aperture (40) comprising a hollow part (41), having an inner surface (42), extending at an interface between different zones (50;60) of the apparatus; and a member (43) positioned in the hollow part configured to substantially transmit EUV radiation and to substantially filter non-EUV radiation at the interface; wherein the inner surface of the hollow part has a surface treatment configured to increase absorption of the non-EUV radiation that is transferred by the member to the hollow part.

A liquid immersion exposure apparatus exposes a substrate with an exposure beam via a liquid immersion area formed on a portion of a surface of the substrate. The apparatus includes a projection system, a first nozzle member having an aperture through which the exposure beam is projected, the first nozzle member having a liquid supply inlet and a liquid recovery outlet, a second nozzle member having a gas supply inlet via which a gas is supplied to a space surrounding the liquid immersion area during the exposure, a driving system which moves the second nozzle member relative to the first nozzle member, and a stage system having a holder which holds the substrate and which is movable relative to and below the projection system, the first nozzle member and the second nozzle member.

Methods for calibrating a photolithographic system are disclosed. A cold lens contour for a reticle design and at least one hot lens contour for the reticle design are generated from which a process window is defined. Aberrations induced by a lens manipulator are characterized in a manipulator model and the process window is optimized using the manipulator model. Aberrations are characterized by identifying variations in critical dimensions caused by lens manipulation for a plurality of manipulator settings and by modeling behavior of the manipulator as a relationship between manipulator settings and aberrations. The process window may be optimized by minimizing a cost function for a set of critical locations.

An immersion lithographic apparatus is disclosed that includes a fluid handling system configured to confine immersion liquid to a localized space between a final element of a projection system and a substrate and/or table and a gas supplying device configured to supply gas with a solubility in immersion liquid of greater than 5×10.sup.−3 mol/kg at 20° C. and 1 atm total pressure to an area adjacent the space.

A lithographic projection apparatus includes a support structure to hold a patterning device, the patterning device configured to pattern a beam of radiation according to a desired pattern; a projection system to project the patterned beam onto a target portion of a substrate; a substrate table configured to hold the substrate, the substrate table including a support surface to support an intermediary plate between the projection system and at least one of the substrate and an object positioned on the substrate table and not in contact with the at least one of the substrate and the object; and a liquid supply system to provide a liquid, through which the beam is to be projected, in a space between the projection system and the at least one of the substrate and the object.

A method for determining an offset between a center of a substrate and a center of a depression in a chuck includes providing a test substrate to the depression, the test substrate having a dimension smaller than a dimension of the depression, measuring a position of an alignment mark of the test substrate while in the depression, and determining the offset between the center of the substrate and the center of the depression from the position of the alignment mark.

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.

Manufacturing of semiconductor devices often involves performed photolithography to pattern and etch the various features of those devices. Such photolithography involves masking and focusing light onto a surface of the semiconductor device for exposing and etching the features of the semiconductor devices. However, due to design specifications and other causes, the semiconductor devices may not have a perfectly flat light-incident surface. Rather, some areas of the semiconductor device may be raised or lowered relative to other areas of the semiconductor device. Therefore, focusing the light on one area causes another to become unfocused. By carefully designing a photomask to cause phase shifts of the light transmitted therethrough, focus across all areas of the semiconductor device can be achieved during photolithography, which results in sharp and accurate patterns formed on the semiconductor device.

An illumination optical device for illuminating a plane to be illuminated using light from a light source, includes: an optical integrator configured to cause an optical intensity distribution to be uniform on an emission end surface by reflecting light incident from an incident end surface in an inside surface a plurality of times; and a light flux forming unit configured to convert a light flux from a focal position where a condensing mirror condenses light from the light source at a first angle with respect to an optical axis directed from the light source to the plane to be illuminated to a light flux to be incident on the incident end surface of the optical integrator at a second angle greater than the first angle with respect to the optical axis, wherein the plane to be illuminated is illuminated with light from the optical integrator.