Patent Number: 058928090
Section: claims

1. A selectable X-ray monochromator comprising: a plurality of X-ray sources located in proximity to each other;  means for selectively activating any one of said X-ray sources;  a plurality of diffracting crystal means wherein each diffracting crystal means has a preset position in space and is capable of focusing X-rays from the selected source to a common image location; and  each diffracting means comprising toroidal crystal means which satisfies the Johann geometry within a plurality of planes containing the source and image location.  a plurality of X-ray sources located in proximity to each other;  means for selectively activating any one of said X-ray sources;  a plurality of diffracting crystal means wherein each diffracting crystal means has a preset position in space and is capable of focusing X-rays from the selected source to a common image location; and  each diffracting means comprising toroidal crystal means which satisfies the Johansson geometry within a plurality of planes containing the source and image location.  a plurality of X-ray sources each of which is capable of emitting characteristic photon energies;  a plurality of diffracting crystal means each of which has a preset position in space and is capable of focusing radiation from one of the said sources onto a sample at a common image position;  means of selectively activating one of said sources to produce radiation that is focused by one of said diffracting crystal means; and  means for detecting and analyzing fluorescence X-rays emitted by the said sample.  means for viewing the sample before X-ray fluorescence analysis; and  means for adjusting the location on the sample at which X-ray fluorescence occurs. 2. The monochromator of claim 1 wherein said preset position of each diffracting crystal means is accomplished by alignment means relative to the selected source and the common image location. 3. The monochromator of claim 2 wherein each of said plurality of diffracting crystal means is contained on a common mounting plate. 4. The monochromator of claim 1 wherein the x-rays are produced by bombardment of a target by a focused energetic electron beam and the electron beam is deflected by an electrostatic field for selecting a target to serve as said source of X-rays. 5. The monochromator of claim 1 wherein the x-rays are produced by bombardment of a target by a focused energetic electron beam and the electron beam is deflected by a magnetic field for selecting a target to serve as said source of X-rays. 6. The monochromator of claim 1 wherein the x-rays are produced by bombardment of a target by a focused energetic electron beam, the targets that serve as said x-ray sources are contained on a common target holder and selection of a particular target is done by motion of said target holder. 7. A selectable X-ray monochromator comprising: 8. The monochromator of claim 7 wherein each diffracting crystal means can be individually aligned relative to the selected source and the common image location. 9. The monochromator of claim 8 wherein each of said plurality of diffracting crystal means is contained on a common mounting plate. 10. The monochromator of claim 7 wherein the x-rays are produced by bombardment of a target by a focused energetic electron beam and the electron beam is deflected by an electrostatic field to select a target to serve as said source of X-rays. 11. The monochromator of claim 7 wherein the x-rays are produced by bombardment of a target by a focused energetic electron beam and the electron beam is deflected by a magnetic field to select a target to serve as said source of X-rays. 12. The monochromator of claim 7 wherein the x-rays are produced by bombardment of a target by a focused energetic electron beam, the targets that serve as said x-ray sources are contained on a common target holder, and selection of a particular target is done by motion of said target holder. 13. Apparatus for X-ray microanalysis comprising: 14. The monochromator of claim 13 wherein said preset position of each diffracting crystal means is accomplished by alignment means relative to the selected source and the common image location. 15. Apparatus of claim 13 wherein the activation of said source is done by deflection of the focal spot of a focused energetic electron beam onto an appropriate target by means of an electric field. 16. Apparatus of claim 13 wherein the activation of said source is done by deflection of the focal spot of a focused energetic electron beam onto an appropriate target by means of a magnetic field. 17. Apparatus of claim 13 wherein the activation of said source is done by movement of a holder which contains electron beam targets, each target becoming an x-ray source when bombarded by a stationary focused energetic electron beam. 18. Apparatus of claim 13 which further comprises: 19. Apparatus of claim 18 wherein means for adjusting the location on the sample at which X-ray fluorescence occurs consists of an x-y table means. 20. Apparatus of claim 19 wherein a storage means is provided for retaining images formed by said viewing means, stored images can be retrieved and presented on a display means, and the display contains a cursor that shows the position of the region analyzed relative to the sample's image.