Patent Number: 
Section: claims

1. A projection objective configured so that during use the projection objective can direct light from an object plane to an image plane, the projection objective comprising:a last optical element on an image side of the objective, wherein the last optical element is plane on the image side and confines, together with the image plane, an immersion space which is configured to be filled with an immersion liquid, andat least one liquid or solid volume, whichhas plane-parallel interfaces,is configured to be introduced into a beam path of the projection objective andhas an optical thickness that is substantially equal to the optical thickness of the immersion space when the immersion space is filled with the immersion liquid,wherein the projection objective is configured to be used in a microlithographic projection exposure apparatus. 2. The objective of claim 1, wherein only refractive surfaces being plane and extending parallel to the image plane are arranged in a beam path between the image plane and the at least one liquid or solid volume which is furthest away from the image plane. 3. The objective of claim 2, wherein the last optical element on the image side is a plane-parallel terminating plate. 4. The objective of claim 1, wherein the at least one liquid or solid volume has a refractive index which is substantially equal to the refractive index of the immersion liquid, and wherein the overall extension of the at least one liquid or solid volume along an optical axis of the objective is substantially equal to the dimension of the immersion space along the optical axis. 5. The objective of claim 4, wherein the overall extension of the at least one liquid or solid volume along the optical axis differs by less than 10 nm from the dimension of the immersion space along the optical axis. 6. The objective of claim 5, wherein the overall extension of the at least one liquid or solid volume along the optical axis differs by less than 1 nm from the dimension of the immersion space along the optical axis. 7. The objective of claim 6, wherein the overall extension of the at least one liquid or solid volume along the optical axis differs by less than 0.1 nm from the dimension of the immersion space along the optical axis. 8. The objective of claim 1, wherein the at least one liquid or solid volume is a liquid, and wherein the objective comprises a sealable intermediate space arranged between two optical elements having mutually facing plane-parallel interfaces, said intermediate space being configured to receive the liquid. 9. The objective of claim 8, wherein the last optical element on the image side is a plane-parallel terminating plate which forms one of the two optical elements. 10. The objective of claim 9, further comprising an immersion device which is configured to fill and empty the immersion space and to fill and empty the intermediate space with the same liquid. 11. The objective of claim 1, wherein the at least one liquid or solid volume is formed by a plane-parallel plate which has the same refractive index as the immersion liquid. 12. A microlithographic projection exposure apparatus comprising the objective of claim 1. 13. A method for converting a projection objective of a microlithographic projection exposure apparatus from dry operation to immersed operation, the method comprising:a) providing a projection objective comprising a last optical element on an image side of the objective, wherein the last optical element is plane on the image side and confines, together with the image plane, an immersion space which is configured to be filled with an immersion liquid;b) removing at least one liquid or solid volume from a location in the beam path of the objective that is different from the immersion space, wherein the at least one liquid or solid volume has plane-parallel interfaces, and has an optical thickness that is substantially equal to the optical thickness of the immersion space when the immersion space is filled with the immersion liquid; andc) filling the immersion space with an immersion liquid which has the same refractive index as the at least one volume removed in step b). 14. The method of claim 13, wherein the at least one liquid or solid volume is liquid, and wherein the liquid volume is removed in step b) and relocated into the immersion space. 15. The method of claim 13, wherein, after exposures have been carried out in immersed operation, the objective is converted back to dry operation by removing the liquid from the immersion space and re-introducing the at least one volume removed in step b) into the beam path of the objective. 16. A method for the microlithographic production of microstructured components, the method comprising:a) providing a support, on at least some of which a layer of a photosensitive material is applied;b) providing a reticle which contains structures to be projected;c) providing the objective of claim 1; andd) projecting at least a part of the reticle onto a region on the layer with the aid of the objective provided in step c). 17. The method of claim 16, wherein the method is used to provide a microstructured component. 18. A projection objective configured so that during use the projection objective can direct light from an object plane to an image plane, the projection objective compnsing:an optical axis,a space whichis configured to be filled with a liquid andis confined by two at least substantially plane-parallel surfaces extending perpendicularly to the optical axis, andat least one liquid or solid volume, whichhas plane-parallel interfaces,is configured to be introduced into a beam path of the projection objective andhas an optical thickness that is substantially equal to the optical thickness of the space when it is filled with the liquid,wherein the projection objective is configured to be used in a microlithographic projection exposure apparatus. 19. The objective of claim 18, wherein only refractive surfaces being plane and extending perpendicular to the optical axis are arranged between the space and the at least one liquid or solid volume which is furthest away from the space. 20. The objective of claim 18, wherein one of the surfaces confining the space coincides with the image plane, and wherein the liquid is an immersion liquid. 21. The objective of claim 20, wherein the at least one liquid or solid volume has a refractive index which is substantially equal to the refractive index of the immersion liquid, and wherein the overall extension of the at least one liquid or solid volume along the optical axis is substantially equal to the dimension of the space along the optical axis. 22. The objective of claim 21, wherein the overall extension of the at least one liquid or solid volume along the optical axis differs by less than 10 nm from the dimension of the space along the optical axis. 23. The objective of claim 22, wherein the overall extension of the at least one liquid or solid volume along the optical axis differs by less than 1 nm from the dimension of the space along the optical axis. 24. The objective of claim 23, wherein the overall extension of the at least one liquid or solid volume along the optical axis differs by less than 0.1 nm from the dimension of the space along the optical axis. 25. The objective of claim 18, wherein the at least one liquid or solid volume is a liquid, and wherein the objective comprises a sealable intermediate space arranged between two optical elements having mutually facing plane-parallel interfaces, said intermediate space being configured to receive the liquid. 26. The objective of claim 25, wherein the space is an immersion space which is contiguous to the image plane, and wherein the objective comprises a plane-parallel terminating plate which is the last optical element on the image side and which separates the intermediate space from the immersion space. 27. The objective of claim 26, further comprising an immersion device which is configured to fill and empty the immersion space and to fill and empty the intermediate space with the same liquid. 28. The objective of claim 18, wherein the at least one liquid or solid volume is formed by a plane-parallel plate which has the same refractive index as the liquid. 29. A microlithographic projection exposure apparatus comprising the objective of claim 18. 30. A method for operating a projection objective of a microlithographic projection exposure apparatus, the method comprising:a) providing a projection objective comprising an optical axis and an empty space which is configured to be filled with a liquid and is confined by two at least substantially plane- parallel surfaces extending perpendicularly to the optical axis;b) carrying out exposures;c) removing at least one liquid or solid volume from a location in the beam path of the objective that is different from the space, wherein the at least one liquid or solid volume has plane-parallel interfaces, and has an optical thickness that is substantially equal to the optical thickness of the space when the space is filled with the liquid; andd) filling the space with a liquid. 31. The method of claim 30, wherein the at least one liquid or solid volume is liquid, and wherein the liquid volume is removed in step c) and relocated into the space in step d). 32. A method for operating a projection objective of a microlithographic projection exposure apparatus, the method comprising:a) providing a projection objective comprising an optical axis and a space which is filled with a liquid and is confined by two at least substantially plane-parallel surfaces extending perpendicularly to the optical axis;b) carrying out exposures;c) removing the liquid from the space andd) introducing at least one liquid or solid volume into a location in the beam path of the objective that is different from the space, wherein the at least one liquid or solid volume has plane-parallel interfaces, and has an optical thickness that is substantially equal to the optical thickness of the space when the space is filled with the liquid. 33. The method of claim 32, wherein the at least one liquid or solid volume is liquid, and wherein the liquid is removed in step c) and introduced into the space in step d).