The present invention is to provide a pellicle characterized by including a pellicle film and a pellicle frame, in which the pellicle film is stretched on the pellicle frame, and the pellicle film is an annealed pellicle film, and to provide a method for producing a pellicle by stretching a pellicle film on a pellicle frame, including the step of annealing the pellicle film alone before stretching the pellicle film on the pellicle frame, annealing the pellicle after stretching the pellicle film on the pellicle frame, or annealing the pellicle film alone and the pellicle both before and after stretching the pellicle film on the pellicle frame.

An alignment system, a dual-wafer-stage system and a measurement system are disclosed, the alignment system including a main frame (201, 301), a first wafer stage (205, 305), an alignment sensor (202, 302), a position acquisition module (208, 308) and a signal processing device (203, 303). The position acquisition module (208, 308) collects positional data from the first wafer stage (205, 305) and the reflector (204, 304) simultaneously. The reflector (204, 304) is arranged on the alignment sensor (202, 302). In other words, positional data of the alignment sensor (202, 302) and positional data of the first wafer stage (205, 305) are collected simultaneously. In addition, the data can be processed to indicate the relative position of the first wafer stage (205, 305) relative to the alignment sensor (202, 302) whose vibration has been zeroed. That is, a position where an alignment mark is aligned can be obtained with the relative vibration amplitude of the alignment sensor (202, 302) being zeroed. This can circumvent the impact of vibration of the alignment sensor (202, 302) and allow increased repeatability accuracy of alignment.

A projection exposure apparatus for semiconductor lithography includes: a light source for generating optical used radiation by which structures arranged on a reticle can be imaged onto a wafer; a plurality of optical elements for guiding and manipulating the used radiation; and a plurality of position sensors for determining the position of at least some of the optical elements. At least some of the position sensors are arranged on a measurement structure that is at least partially decoupled mechanically and/or thermally from the further components of the projection exposure apparatus. The measurement structure has at least two mechanically decoupled substructures. The first substructure has a lower coefficient of thermal expansion than the second substructure. The second substructure has a greater stiffness than the first substructure.

A positioning system for moving or positioning a moveable object, the system including: a dynamic support system including a reaction mass, a first support, a first spring system to support the reaction mass from the first support, a second support, a second spring system to support the first support from the second support, and a damping system to provide damping to the dynamic support system; and an actuator for generating a driving force between the moveable object and the reaction mass for moving or position the object, wherein a first eigenfrequency and a second eigenfrequency of the dynamic support system are substantially the same.

A supporting member on which a wafer table is mounted is substantially kinematically supported, via six rod members placed on a slider. Further, coupling members are placed facing in a non-contact manner via a predetermined gap, thin plate-shaped edges provided at both ends in the Y-axis direction of the supporting member. By this arrangement, vibration-damping is performed by the coupling members (squeeze dampers) facing the edges, on vibration of the supporting member mounted on the wafer table. Further, because the supporting member is kinematically supported via the plurality of rod members, it becomes possible to reduce deformation of the wafer table that accompanies deformation of the slider.

A lithographic apparatus includes an optical sensor, a movable body, a support, a deflector system, a first drive system and a second drive system. The movable body is moveable relative to the sensor. The support is for holding the sensor. The first drive system is arranged to move the movable body relative to the sensor. The second drive system is arranged to move the first drive system relative to the sensor. The second drive system is arranged to move the deflector system relative to the sensor. A disturbance is induced by a movement of the movable body. The deflector system is arranged to create a deflecting area for reflecting the disturbance away from the support.

A photolithography tool and a method for compensating for surface deformation in a carrier of the photolithography tool are disclosed. In the photolithography tool, carrier surface deformation compensation elements are provided at the bottom of the carrier, which are capable of compensating for the surface deformation in the carrier. In the method, the surface deformation is detected by carrier surface deformation detection modules, and an automated closed-loop controller controls compensating forces exerted by the carrier surface deformation compensation elements based on the detected deformation. This allows more accurate compensation for the carrier surface deformation.

The disclosure relates to a device for transmitting electrical signals between a first interface element, arranged at a first structure of a lithography system, and a second interface element, arranged at a second structure of the lithography system. An electrical conductor connects the first interface element and the second interface element. The device has a hollow body which surrounds at least sections of the electrical conductor and which is designed to electromagnetically shield the electrical conductor. A gap is provided in the hollow body or between the hollow body and one of the structures and allows a relative movement of the first structure and the second structure to mechanically decouple the first structure from the second structure.

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.

An antivibration device which can enhance the antivibration characteristic in the horizontal direction is provided. An antivibration device 10 includes: a support part 100 supported by at least one first viscoelastic body 400 so as to permit circumferential movement; a carrying part 200 to which a target object 900 for antivibration is mounted; a connecting mechanism 300 connecting the support part 100 with the carrying part 200; wherein the connecting mechanism 300 has at least one second viscoelastic body 350 which permits the circumferential movement of the carrying part 200 with respect to the support part 100. Preferably, the connecting mechanism 300 further includes a suspending plate 302 suspending the carrying part 200; wherein the suspending plate 302 is supported by at least one of the second viscoelastic bodies 350 from the lower side in the gravitational direction.