Patent Number: 051075261
Section: claims

1. An x-ray microscope for high resolution imaging in a narrow band at wavelengths where x-rays are absorbed by carbon and for which water within biological specimens or the like is transparent so that microscopic structures within said specimens which are carbon based may be imaged with high contrast, said microscope comprising: a hollow mounting tube having a stage end and an image end at respective ends of said tube, filter means mounted at an object plane disposed adjacent said stage end for carrying a specimen to be illuminated by an x-ray source having a range of wavelengths including wavelengths within said band, primary and secondary normal incidence mirror substrates disposed within said mounting tube, each of said mirror substrates having an ultra-smooth mirror surface finish, an identical multilayer coating carried on the mirror surfaces of said primary and secondary substrates for reflecting with high efficiency radiation within said narrow band while providing low reflectivity outside of said band, first mounting means for positioning said primary mirror substrate for receiving radiation transmitted through a specimen mounted on said filter means and for reflecting radiation to said secondary mirror substrate, second mounting means for positioning said secondary mirror substrate for receiving radiation from said primary mirror substrate and for reflecting said radiation to an image plane adjacent said image end, and an x-ray detector sensitive to wavelengths within said band disposed at said image plane. 2. A x-ray microscope as recited in claim 1, wherein said primary mirror comprises a concave spherical surface and said secondary mirror comprises a convex spherical surface said spherical surfaces having a common center of curvature disposed intermediate said stage end and said secondary mirror. 3. An x-ray microscope as recited in claim 2, wherein said primary mirror has an annular configuration with a central aperture, said secondary mirror being disposed intermediate said primary mirror and said center of curvature for reflecting radiation through said aperture to said detector. 4. An x-ray microscope as recited in claim 3, wherein said primary and secondary mirrors define an optical system having an optical axis, said optical axis passing through said aperture, and said center of curvature being disposed on said optical axis. 5. An x-ray microscope as recited in claim 1, wherein said multilayer coating has a high reflectivity in a wavelength band between 23.3 and 43.7 angstroms and a low reflectivity outside said wavelength band. 6. An x-ray microscope as recited in claim 5, wherein said mirror substrates each have a surface smoothness in the order of 0.5 to 3 angstroms RMS. 7. An x-ray microscope as recited in claim 6, wherein said coating reflects x-rays by diffraction in accordance with the Bragg relation and the wavelength at which peak reflectivity by first order diffraction occurs is approximately 36 angstroms. 8. An x-ray microscope as recited in claim 7, wherein said primary mirror comprises a concave spherical surface and said secondary mirror comprises a convex spherical surface, said spherical surfaces having a common center of curvature disposed intermediate said stage end and said secondary mirror. 9. An x-ray microscope as recited in claim 8, wherein said primary mirror has an annular configuration with a central aperture, said secondary mirror being disposed intermediate said primary mirror and said center of curvature for reflecting radiation through said aperture to said detector. 10. An x-ray microscope as recited in claim 9, wherein said primary and secondary mirrors define an optical system having an optical axis, said optical axis passing through said aperture, and said center of curvature being disposed on said optical axis. 11. An x-ray microscope as recited in claim 1, wherein said filter means comprises a foil of titanium supported on a nickel mesh for preventing visible light radiation to be transmitted from said source to said primary and secondary mirror substrates. 12. An x-ray microscope as recited in claim 1, wherein said detector comprises photographic film. 13. An x-ray microscope as recited in claim 4, wherein the radius R.sub.1 of the primary mirror substrate, the radius R.sub.2 of the secondary mirror substrate and the distance Z.sub.0 from the center of curvature to the specimen conforms to the equation R.sub.2 /R.sub.1 =1.5-R.sub.2 /Z.sub.0 .+-.(1.25-R.sub.2 /Z.sub.0).sup.1/2. 14. Apparatus for imaging microscopic structures within biological specimens comprising, a vacuum chamber and means for mounting an x-ray microscope mounted within said chamber, said microscope comprising a hollow mounting tube having a stage end and an image end at respective ends of said tube, filter means mounted at an object plane disposed adjacent said stage end for carrying a specimen to be illuminated by an x-ray source having a range of wavelengths including wavelengths within a narrow band where x-rays are absorbed by carbon and not absorbed by water within said specimens, primary and secondary normal incidence mirror substrates disposed within said mounting tube, each of said mirror substrates having an ultra-smooth mirror surface finish, an identical multilayer coating carried on the mirror surfaces of said primary and secondary substrates for enhancing the reflectivity of radiation within said narrow band while providing low reflectivity outside of said band, first mounting means for positioning said primary mirror substrate for receiving radiation transmitted through a specimen mounted on said filter means and for reflecting radiation to said secondary mirror substrate, second mounting means for positioning said secondary mirror substrate for receiving radiation from said primary mirror substrate and for reflecting said radiation to an image plane adjacent said image end, and an x-ray detector sensitive to wavelengths within said band disposed at said image plane. 15. Apparatus as recited in claim 14, wherein said primary mirror comprises a concave spherical surface and said secondary mirror comprises a convex spherical surface, said spherical surfaces having a common center of curvature disposed intermediate said stage end and said secondary mirror. 16. Apparatus as recited in claim 15, wherein said primary mirror has an annular configuration with a central aperture, said secondary mirror being disposed intermediate said primary mirror and said center of curvature for reflecting radiation through said aperture to said detector. 17. Apparatus as recited in claim 16, wherein said primary and secondary mirrors define an optical system having an optical axis, said optical axis passing through said aperture, and said center of curvature being disposed on said optical axis. 18. Apparatus as recited in claim 14, wherein said multilayer coating has a high reflectivity in a wavelength band between 23.3 and 43.7 angstroms and a low reflectivity outside said wavelength band. 19. Apparatus as recited in claim 18, wherein said mirror substrates each have a surface smoothness in the order of 0.7 to 3 angstroms RMS. 20. Apparatus as recited in claim 19, wherein said coating reflects x-rays by diffraction in accordance with the Bragg relation and the wavelength at which peak reflectivity by first order diffraction occurs is approximately 36 angstroms.