X-ray scanners and X-ray sources therefor

The invention claimed is: 1. An X-ray scanner comprising a first electron source configured to generate a first electron beam; and an anode having a target surface comprising a first material and a second material, wherein said first material is different from said second material, said first material and second material form a pattern on said target surface, the pattern comprising an elongated strip of the first material alternating with an elongated strip of the second material to form an array of alternating target areas in a ring around said scanner, the first electron source is configured to irradiate a strip of both the first material and second material simultaneously. 2. The X-ray scanner of claim 1 wherein the first and second material are formed of a uniform material. 3. The X-ray scanner of claim 1 wherein, upon irradiating the strip of both the first material and second material simultaneously, a composite X-ray spectrum is generated having an energy spectrum that is a sum of a spectra of the first material and a spectra of the second material. 4. The X-ray scanner of claim 1 further comprising a second electron source configured to generate a second electron beam. 5. The X-ray scanner of claim 1 wherein the first material area comprises a strip that extends in a direction parallel to the scanning direction. 6. The X-ray scanner of claim 1 wherein the second material area comprises a strip that extends in a direction parallel to the scanning direction. 7. The X-ray scanner of claim 1 wherein the first material area comprises a strip that extends in a direction which is oblique to the scanning direction. 8. The X-ray scanner of claim 1 wherein the second material area comprises a strip that extends in a direction which is oblique to the scanning direction. 9. The X-ray scanner of claim 1 wherein the first material area comprises a strip that extends in a direction which is transverse to the scanning direction. 10. The X-ray scanner of claim 1 wherein the second material area comprises a strip that extends in a direction which is transverse to the scanning direction. 11. The X-ray scanner of claim 1 wherein the first or second material area comprises a thin film of metal. 12. The X-ray scanner of claim 1 further comprising detectors, wherein the detectors comprise a first set of detectors and a second set of detectors and wherein, relative to said second set of detectors, the first set of detectors is more sensitive to X-rays over a spectra generated from irradiating the first material, and, relative to said first set of detectors, the second set of detectors is more sensitive to X-rays over a spectra generated from irradiating the second material. 13. The X-ray scanner of claim 12 wherein the second set of detectors comprises a filter material and a detector element. 14. The X-ray scanner of claim 1 further comprising detectors, wherein the detectors comprise a first set of detectors and a second set of detectors and wherein said first set of detectors has a different response characteristic from said second set of detectors and wherein the first set of detectors is configured to receive X-rays of a first energy spectra and the second set of detectors is configured to receive X-rays of a second energy spectra. 15. The X-ray scanner of claim 1 wherein the first and second materials are each arranged to generate X-rays having an intensity peak at two different respective fluorescent energies, and a filter material is arranged to provide different attenuations at the two fluorescent energies. 16. The X-ray scanner of claim 15 wherein the filter material has an absorption edge at a frequency between the two fluorescent energies. 17. A method of generating X-rays comprising providing at least one electron source; providing an anode with a target surface formed with parallel, elongated, alternating sections of at least two different material areas spaced along the target surface in a scanning direction; and directing an electron beam from the at least one electron source to simultaneously irradiate both of said at least two different material areas to generate an X-ray beam of at least two different energy spectra. 18. The method of generating X-rays of claim 17 further comprising detecting radiation using a first set of detectors and a second set of detectors and wherein said first set of detectors has a different response characteristic from said second set of detectors and wherein the first set of detectors is configured to receive X-rays of a first energy spectra and the second set of detectors is configured to receive X-rays of a second energy spectra. 19. The method of generating X-rays of claim 17 further comprising detecting radiation using a first set of detectors and a second set of detectors and wherein, relative to said second set of detectors, the first set of detectors is more sensitive to X-rays over a spectra generated from irradiating a first of the at least two different material areas, and, relative to said first set of detectors, the second set of detectors is more sensitive to X-rays over a spectra generated from irradiating a second of the at least two different material areas.