Abstract: The present invention provides a lithographic apparatus comprising an illumination system for providing a projection beam of radiation. The illumination system comprises at least one movable optical element (7), such that a projection beam of radiation (4) can be shifted around a central position. This ensures that inhomogeneities in the intensity distribution in the projection beam (4) will be smeared out, which in turn provides an improved homogeneity of the exposure of a surface to be illuminated by the system, such as a wafer or other substrate. The optical element (7) may comprise a motor movable mirror, prism, filter, lens, axicon, diffuser, diffractive optical array, optical integrator, etc. The invention further provides a device manufacturing method, using a lithographic apparatus according to the invention, wherein the optical element is moved, in order to provide an optimum homogeneity for the projection beam of radiation.

Abstract: A lithographic projection apparatus includes a radiation system for providing a projection beam of radiation, a support structure for supporting a patterning device, the patterning device serving to pattern the projection beam according to a desired pattern, a substrate table for holding a substrate, a projection system for projecting the patterned beam onto a target portion of the substrate, an illumination system for conditioning the beam of radiation beam so as to provide a conditioned radiation beam so as to be able to illuminate said patterning means, and a beam delivery system including redirecting elements for redirecting and delivering the projection beam from the radiation system to the illumination system. The radiation beam is arranged to have a predetermined polarization state and the redirecting elements are arranged to provide a minimum radiation loss in relation to the predetermined polarization state of the radiation beam.

Abstract: The invention relates to an illumination assembly, including a beam expander being arranged for receiving from a radiation source a radiation beam directed in a first direction (z) and for expanding the beam with a first magnification factor in a second direction (x) and with a second magnification factor in a third direction (y). The first, second and third directions being substantially mutually orthogonal. The illumination assembly further includes a beam splitter that is arranged for splitting the radiation beam in two split radiation beams split in at least one of the second and third direction, the propagation direction of the split radiation beams being substantially in the first direction. The beam splitter is further arranged for delivering the split radiation beams to the beam expander, of which at least one of the magnification factors is adjustable.

Abstract: A pulse modifying unit is provided in the illumination system of the lithographic apparatus to reduce the degradation of the expensive lens elements by billions of the high intensity ultraviolet pulses from the laser is configured to receive an input pulse of radiation along a first optical axis and further configured to emit one or more corresponding output pulses of radiation along a second optical axis, including a divider disposed along the first optical axis and configured to divide the incoming pulse into a first and a second pulse portion, wherein the divider is further configured to direct the first pulse portion along the second optical axis. A first and a second mirror, each with a radius of curvature, are disposed facing each other with a predetermined separation, configured to receive the second pulse portion and to redirect the second portion along the second optical axis.

Abstract: An optical attenuator device operates to remove a part of a beam of radiation having a higher than average intensity using at least one optical attenuator element. The device has application in a radiation system, and/or a lithographic apparatus, in particular a scanning lithographic apparatus, wherein the optical attenuator element(s) are provided in a central part of the beam, for example perpendicularly to a scanning direction.

Abstract: The invention relates to an illumination assembly, including a beam expander being arranged for receiving from a radiation source a radiation beam directed in a first direction (z) and for expanding the beam with a first magnification factor in a second direction (x) and with a second magnification factor in a third direction (y). The first, second and third directions being substantially mutually orthogonal. The illumination assembly further includes a beam splitter that is arranged for splitting the radiation beam in two split radiation beams split in at least one of the second and third direction, the propagation direction of the split radiation beams being substantially in the first direction. The beam splitter is further arranged for delivering the split radiation beams to the beam expander, of which at least one of the magnification factors is adjustable.

Abstract: A lithographic apparatus includes an illumination system including a field faceted mirror including a plurality of field facets and configured to receive radiation from a radiation source and form a plurality of images of the radiation source on corresponding pupil facets of a pupil faceted mirror. Each of the field facets is configured to provide an illumination slit at a level of a patterning device. The illumination slits are summed together at the level of the patterning device to illuminate the patterning device. First blades are configured to block radiation from a radiation source and each first blade is selectively actuable to cover a portion of a selectable number of field facets. The field faceted mirror further comprises partial field facets, the partial field facets being configured to produce a partial illumination slit at the level of the patterning device, and the pupil faceted mirror further includes pupil facets corresponding to the partial field facets.

Abstract: A lithographic apparatus comprises an illumination system for providing a projection beam of radiation. A support structure is provided for supporting a patterning device, the patterning device serving to impart the projection beam with a pattern in its cross-section. A substrate table holds a substrate, while a projection system projects the patterned beam onto a target portion of the substrate. The illumination system comprises a field defining element arranged to define an illuminating field in the plane of the patterning device or in a plane conjugate thereto, the field being off-axis with respect to the optical axis of the illuminating system.

Abstract: A lithographic projection apparatus includes an illumination system having a reflective integrator with a rectangular cross-section. An optical element is provided to redistribute an intensity distribution exiting the reflective integrator.

Abstract: A projection beam PB is projected onto a substrate W via a mask MA. The direction dependence of the intensity of the beam at the substrate W is controlled by passing the beam through a series of optical elements 120a-b in front of a pupil plane 14. The intensity distribution as a function of position in the pupil plane 14 determines the angle dependence at the substrate W. The optical elements 120a-b, which are preferably arrays of microlenses (or more particularly DOE's: Diffractive Optical Elements) each define an angle dependence of the intensity of the beam PB. The optical elements 120a-b are each arranged to pass a major part of the beam PB substantially without deflection and a minor part with a deflection angle dependent intensity. The major part of the beam is blocked out of the beam behind the series of optical elements 120a-b. As a result an addition of the effects of upon the intensity in the pupil plane 14 is realized.

Abstract: The present invention provides a lithographic apparatus comprising an illumination system for providing a projection beam of radiation. The illumination system comprises at least one movable optical element (7), such that a projection beam of radiation (4) can be shifted around a central position. This ensures that inhomogeneities in the intensity distribution in the projection beam (4) will be smeared out, which in turn provides an improved homogeneity of the exposure of a surface to be illuminated by the system, such as a wafer or other substrate. The optical element (7) may comprise a motor movable mirror, prism, filter, lens, axicon, diffuser, diffractive optical array, optical integrator, etc. The invention further provides a device manufacturing method, using a lithographic apparatus according to the invention, wherein the optical element is moved, in order to provide an optimum homogeneity for the projection beam of radiation.

Abstract: An optical attenuator device operates to remove a part of a beam of radiation having a higher than average intensity using at least one optical attenuator element. The device has application in a radiation system, and/or a lithographic apparatus, in particular a scanning lithographic apparatus, wherein the optical attenuator element(s) are provided in a central part of the beam, for example perpendicularly to a scanning direction.

Abstract: A projection beam PB is projected onto a substrate W via a mask MA. The direction dependence of the intensity of the beam at the substrate W is controlled by passing the beam through a series of optical elements 120a-b in front of a pupil plane 14. The intensity distribution as a function of position in the pupil plane 14 determines the angle dependence at the substrate W. The optical elements 120a-b, which are preferably arrays of microlenses (or more particularly DOE's: Diffractive Optical Elements) each define an angle dependence of the intensity of the beam PB. The optical elements 120a-b are each arranged to pass a major part of the beam PB substantially without deflection and a minor part with a deflection angle dependent intensity. The major part of the beam is blocked out of the beam behind the series of optical elements 120a-b. As a result an addition of the effects of upon the intensity in the pupil plane 14 is realized.

Abstract: A lithographic projection apparatus comprising: a radiation system for providing a projection beam of radiation; a support structure for supporting patterning means, the patterning means serving to pattern the projection beam according to a desired pattern; a substrate table for holding a substrate; a projection system for projecting the patterned beam onto a target portion of the substrate; an illumination system for conditioning said beam of radiation beam so as to provide a conditioned radiation beam so as to be able to illuminate said patterning means; and a beam delivery system comprising redirecting elements for redirecting and delivering said projection beam from said radiation system to said illumination system. The radiation beam is arranged to have a predetermined polarization state and said redirecting elements are arranged to provide a minimum radiation loss in relation to said predetermined polarization state of said radiation beam.