Abstract: An imaging optical system that has liquid interposed in an optical path to the image plane to achieve a large effective image-side numerical aperture larger than, for example, 1.4, while a relatively large effective imaging region can be achieved. The imaging optical system that projects an image of a first surface onto a second surface. The optical path between the projection optical system and the second surface can be filled with liquid with a refractive index larger than 1.5, where a refractive index of gas in an optical path within the imaging optical system is 1. The imaging optical system comprises a boundary lens that can be contacted with the gas on the side of the first surface and that can be contacted with the liquid on the side of the second surface, and the boundary lens has a positive refracting power and is made of an optical material having a refractive index larger than 1.8.

Abstract: An immersion projection optical system having, for example, a catadioptric and off-axis structure, reduces the portion of an image space filled with liquid (immersion liquid). The projection optical system, which projects a reduced image of a first plane onto a second plane through the liquid, includes a refractive optical element (Lp) arranged nearest to the second plane. The refractive optical element includes a light emitting surface (Lpb) shaped to be substantially symmetric with respect to two axial directions (XY-axes) perpendicular to each other on the second plane. The light emitting surface has a central axis (Lpba) that substantially coincides with a central axis (40a) of a circle (40) corresponding to a circumference of a light entering surface (Lpa) of the refractive optical element. The central axis of the light emitting surface is decentered in one of the two axial directions (Y-axis) from an optical axis (AX).

Abstract: A projection optical system PL for forming an image of a first plane M on a second plane P has at least one first wedge prism 4 each of an entrance surface and an exit surface of which has a plane and in which a predetermined first wedge angle is made between the plane of the entrance surface and the plane of the exit surface, and when a coordinate system is so defined that a Z-axis direction is set along a direction of a normal to the first plane M, an X-axis direction along a direction of an intersecting line between the plane of the entrance surface and the plane of the exit surface, and a Y-axis direction along a direction perpendicular to the Z-axis direction and the X-axis direction, the first wedge prism 4 is arranged rotatably substantially around the Y-axis direction.

Abstract: A catadioptric imaging optical system of a high numerical aperture in which various aberrations are properly corrected without using a reflection surface having an aspherical shape of high order or a reciprocal optical element. The catadioptric imaging optical system forms an image of a first plane on a second plane and includes a first imaging system for forming a first intermediate image of the first plane based on light from the first plane, a second imaging system having two concave reflection mirrors for forming a second intermediate image of the first plane based on light from the first intermediate image, and a third imaging system for forming a final image of the first plane on the second plane based on light from the second intermediate image. The two concave reflection mirrors have prolate spheroidal-shaped reflection surfaces.

Abstract: A liquid immersion type projection optical system that can stably prevent the outflow of immersion liquid into inside of an optical system and can maintain good imaging performance. In the projection optical system of the present invention, an optical path between a light transmitting member (Lp) disposed closest to a second surface (W) side and the second surface is filled with a liquid (Lm1) having a refractive index greater than 1.1, and a light shielding film (36) for shielding the passing of light is formed on the side surfaces (41, 42) of the light transmitting member. When D is a space between the second surface and the light shielding film, ? is a maximum incident angle of an image forming beam which reaches the second surface, and Ym is a maximum image height on the second surface, the condition of 0.25<D/Ym×tan ?<1.7 is satisfied.

Abstract: An immersion projection optical system that prevents leakage of a liquid (immersion liquid) into the optical system and maintains satisfactory imaging capability. The projection optical system of the present invention is a projection optical system that projects a reduced image of a first plane onto a second plane through a liquid. The projection optical system includes an interface optical lens (Lb) having a side towards the first plane that contacts a gas and a side towards the second plane that contacts the liquid. The interface optical element includes a light entering surface (Lba), which has a convex shape facing towards the first plane, and a groove (Gr), which is formed to surround an effective region in a light emitting surface of the interface optical element.

Abstract: A catadioptric projection optical system for forming a reduced image of a first surface (R) on a second surface (W) is a relatively compact projection optical system having excellent imaging performance as well corrected for various aberrations, such as chromatic aberration and curvature of field, and being capable of securing a large effective image-side numerical aperture while suitably suppressing reflection loss on optical surfaces. The projection optical system comprises at least two reflecting mirrors (CM1, CM2), and a boundary lens (Lb) whose surface on the first surface side has a positive refracting power, and an optical path between the boundary lens and the second surface is filled with a medium (Lm) having a refractive index larger than 1.1.

Abstract: A liquid immersion type projection optical system that can stably prevent the outflow of immersion liquid into inside of an optical system and can maintain good imaging performance. In the projection optical system of the present invention, an optical path between a light transmitting member (Lp) disposed closest to a second surface (W) side and the second surface is filled with a liquid (Lm1) having a refractive index greater than 1.1, and a light shielding film (36) for shielding the passing of light is formed on the side surfaces (41, 42) of the light transmitting member. When D is a space between the second surface and the light shielding film, ? is a maximum incident angle of an image forming beam which reaches the second surface, and Ym is a maximum image height on the second surface, the condition of 0.25<D/Ym×tan ?<1.7 is satisfied.

Abstract: An optical system is able to achieve a substantially azimuthal polarization state in a lens aperture while suppressing loss of light quantity, based on a simple configuration. The optical system of the present invention is provided with a birefringent element for achieving a substantially circumferential distribution or a substantially radial distribution as a fast axis distribution in a lens aperture, and an optical rotator located behind the birefringent element and adapted to rotate a polarization state in the lens aperture. The birefringent element has an optically transparent member which is made of a uniaxial crystal material and a crystallographic axis of which is arranged substantially in parallel with an optical axis of the optical system. A light beam of substantially spherical waves in a substantially circular polarization state is incident to the optically transparent member.

Abstract: An optical system is able to achieve a substantially azimuthal polarization state in a lens aperture while suppressing loss of light quantity, based on a simple configuration. The optical system of the present invention is provided with a birefringent element for achieving a substantially circumferential distribution or a substantially radial distribution as a fast axis distribution in a lens aperture, and an optical rotator located behind the birefringent element and adapted to rotate a polarization state in the lens aperture. The birefringent element has an optically transparent member which is made of a uniaxial crystal material and a crystallographic axis of which is arranged substantially in parallel with an optical axis of the optical system. A light beam of substantially spherical waves in a substantially circular polarization state is incident to the optically transparent member.

Abstract: An optical system is able to achieve a substantially azimuthal polarization state in a lens aperture while suppressing loss of light quantity, based on a simple configuration. The optical system of the present invention is provided with a birefringent element for achieving a substantially circumferential distribution or a substantially radial distribution as a fast axis distribution in a lens aperture, and an optical rotator located behind the birefringent element and adapted to rotate a polarization state in the lens aperture. The birefringent element has an optically transparent member which is made of a uniaxial crystal material and a crystallographic axis of which is arranged substantially in parallel with an optical axis of the optical system. A light beam of substantially spherical waves in a substantially circular polarization state is incident to the optically transparent member.

Abstract: A liquid immersion type projection optical system that can stably prevent the outflow of immersion liquid into inside of an optical system and can maintain good imaging performance. In the projection optical system of the present invention, an optical path between a light transmitting member (Lp) disposed closest to a second surface (W) side and the second surface is filled with a liquid (Lm1) having a refractive index greater than 1.1, and a light shielding film (36) for shielding the passing of light is formed on the side surfaces (41, 42) of the light transmitting member. When D is a space between the second surface and the light shielding film, ? is a maximum incident angle of an image forming beam which reaches the second surface, and Ym is a maximum image height on the second surface, the condition of 0.25<D/Ym×tan ?<1.7 is satisfied.

Abstract: An immersion optical system includes a plurality of lenses disposed along a light beam path of the immersion optical system. The plurality of lenses include a liquid immerged lens which is contactable with a liquid layer. An optically conjugate point of an object surface is formed in the light beam path of the immersion optical system. The object surface is contactable with a liquid.

Abstract: An imaging optical system is a system of a liquid immersion type permitting a plane-parallel plate in liquid to be replaced with another, without substantial degradation of imaging performance, while ensuring sufficiently high laser resistance of a boundary lens. The imaging optical system is provided with a first optically transparent member located nearest to a second plane, and a second optically transparent member located adjacent to the first optically transparent member. An optical path between the first optically transparent member and the second plane is fillable with a first liquid and an optical path between the first optically transparent member and the second optically transparent member is fillable with a second liquid. The imaging optical system satisfies the condition of 1<D1/(M1+M2)<20, where D1 is a center thickness of the first optically transparent member, M1 a center thickness of a layer of the first liquid, and M2 a center thickness of a layer of the second liquid.

Abstract: An optical system for ultraviolet light includes a plurality of optical elements made of a material transparent to ultraviolet light. At least two of the optical elements are utilized for forming at least one liquid lens group that has a first delimiting optical element, a second delimiting optical element, and a liquid lens, which is arranged in an interspace between the first delimiting optical element and the second delimiting optical element and contains a liquid transparent to ultraviolet light.

Abstract: A projection lens of a microlithographic projection exposure apparatus includes a final lens element and a terminating element having no overall refractive power that is positioned between, but spaced apart from, the final lens element and an image plane of the projection lens. The image plane is adjustably positioned such that a position of the image plane with respect to the final lens element is adjustable.

Abstract: A lithographic projection apparatus is arranged to project a pattern from a patterning device onto a substrate using a projection system and has a liquid supply system configured to at least partly fill a space between the projection system and the substrate with a liquid. An element of the projection system through which the pattern is projected has, on a surface configured to be in contact with the liquid, a protective coating which is SiO2.

Abstract: A liquid immersion optical system includes a first optically transparent member and a second optically transparent member, arranged in an optical path between the first optically transparent member and an object. A first space between the first optically transparent member and the second optically transparent member is fillable with a first liquid. A second space between the second optically transparent member and the object is fillable with a second liquid. The second optically transparent member is detachably arranged in the optical path between the first optically transparent member and the object.

Abstract: In a liquid immersion type projection optical system for forming an image of a first plane on a second plane, an optical path between the optical system and the second plane is filled with a liquid having the refractive index larger than 1.5, and the optical system has a boundary optical element whose surface on the first plane side is in contact with a gas and whose surface on the second plane side is in contact with the liquid. The optical system satisfies the condition of 3.2<Nb·Eb/|Rb|<4.0, where Rb is a radius of curvature of the surface on the first plane side of the boundary optical element, Eb an effective diameter of the surface on the first plane side of the boundary optical element, and Nb a refractive index for used light, of an optical material forming the boundary optical element.

Abstract: A projection objective includes at least four curved mirrors, which include a first curved mirror that is a most optically forward mirror and a second curved mirror that is a second most optically forward mirror, as defined along a light path. In addition, an intermediate lens element is disposed physically between the first and second mirrors, the intermediate lens element being a single pass type lens. The objective forms an image with a numerical aperture of at least substantially 1.0 in immersion.