A reticle stage is provided, including an electrostatic chuck and an acoustic wave transducer. The electrostatic chuck includes multiple chucking electrodes embedded in a dielectric body and configured to secure a reticle to a chuck surface of the dielectric body by electrostatic attraction. The acoustic wave transducer is disposed on the chuck surface and configured to impart a surface acoustic wave to the chuck surface to vibrate the chuck surface, thereby removing the reticle from the reticle stage.

The invention relates to a vibration isolation system (VIS) comprising: a base (10); a coupling element (20) to be coupled to a vibration sensitive object; a vibration isolator (30-34) arranged between the base and the coupling element; a bellows (50) to be arranged between the VIS coupling element or the vibration isolator and a protective housing (40) surrounding the vibration sensitive object; and one or more separate damping elements to act on convolutions of the bellows.

A method localizes assembly errors during the arrangement and/or the assembly of in particular vibration-isolated structural elements, in particular of components of optical arrangements, preferably of microlithographic projection exposure apparatuses.

The stage apparatus according to the present invention includes a first stage configured to be movable in a first direction, a first driving unit configured to generate a thrust force to move the first stage in the first direction, and a reaction force reducing unit configured to generate a thrust force to reduce a reaction force generated by the generation of the thrust force of the first driving unit. The reaction force reducing unit can generate the thrust forces with different magnitudes from each other at a plurality of positions in a second direction perpendicular to the first direction, and can generate the thrust forces with different magnitudes from each other at a plurality of positions in a third direction perpendicular to the first direction and the second direction.

Embodiments of the present disclosure relate to projection stabilization systems and maskless lithography systems having projection stabilization systems. The projection stabilization system compensates for propagating vibrations that move image projection systems (IRS's). The IRS's are in a processing positon prior to operation of the maskless lithography process. One or more stiffeners are coupled to the IPS. The one or more stiffeners apply pressure to flexures coupled to each stiffener. The flexures are coupled to the IPS to provide stabilization to the IPS during the operations of the maskless lithography process. For example, the one or more of stiffeners protect the IPS from vibrations that propagate through the system during operation.

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.

A lithographic apparatus is described, the lithographic apparatus comprising: an illumination system configured to condition a radiation beam; a support constructed to support a patterning device, the patterning device being capable of imparting the radiation beam with a pattern in its cross-section to form a patterned radiation beam; a projection system configured to project the patterned radiation beam onto a target portion of a substrate, a stage assembly comprising: a substrate table constructed to hold the substrate; and a positioning device configured to displace the substrate table relative to the projection system; a base frame onto which stage assembly and the projection system are mounted; the base frame comprising a first portion configured to support the stage assembly and a second portion configured to support the projection system, the first portion and the second portion being connected to each other via a compliant portion of the base frame.

Support arrangement for supporting a radiation projection system in a substrate processing apparatus, the support arrangement comprising: a support body for supporting the radiation projection system; electrical wiring for supplying voltages to components within the radiation projection system and/or for supplying control data for modulation of radiation to be projected onto a target surface by the radiation projection system; optical fibers, for supplying control data for modulation of radiation to be projected onto a target surface by the radiation projection system, and a cooling arrangement comprising one or more fluid conduits for cooling the radiation projection system; the electrical wiring, the optical fibers, and the cooling arrangement being at least partly accommodated in and/or supported by the support body.

In a substrate stage, when a Y coarse movement stage moves in the Y-axis direction, an X coarse movement stage, a weight cancellation device, and an X guide move integrally in the Y-axis direction with the Y coarse movement stage, and when the X coarse movement stage moves in the X-axis direction on the Y coarse movement stage, the weight cancellation device move on the X guide in the X-axis direction integrally with the X coarse movement stage. Because the X guide is provided extending in the X-axis direction while covering the movement range of the weight cancellation device in the X-axis direction, the weight cancellation device is constantly supported by the X guide, regardless of its position. Accordingly, a substrate can be guided along the XY plane with good accuracy.

There is provided a projection optical system that projects an image of an object onto an image plane. The projection optical system includes an imaging optical system including a first concave mirror, a convex mirror, and a second concave mirror; an optical member having a first reflecting surface and a second reflecting surface each redirecting an optical path; and a supporting member that supports the convex mirror. The first reflecting surface, the first concave mirror, the convex mirror, the second concave mirror, and the second reflecting surface are provided in that order in a direction of travel of light from an object plane. The optical member has a through hole having an opening on a side facing the convex mirror. The supporting member extends through the through hole and from the opening to the convex mirror.