High-energy X-ray-spectroscopy-based inspection system and methods to determine the atomic number of materials

We claim: 1. An X-ray scanning system for identifying material composition of an object being scanned comprising: at least one X-ray source for projecting an X-ray beam on the object, at least a portion of the projected X-ray beam being transmitted through the object; at least two arrays of detectors, wherein one of said at least two arrays of detectors comprises scintillator material having at least one of Lanthanum Bromide or Lutetium Yttrium Ortho-Silicate, measures an energy spectra of the transmitted X-rays, and generates an image having a first resolution, and wherein a second of said at least two arrays of detectors comprises scintillator material having at least one of Cesium Iodide or Cadmium Tungstate and generates an image having a second resolution, said second resolution being greater than the first resolution; and a processor for identifying the material composition of said object wherein said processor determines the material composition using said spectra. 2. The X-ray scanning system of claim 1 wherein the second one of said at least two arrays of detectors detects said transmitted X-rays and generates a transmission image. 3. The X-ray scanning system of claim 2 wherein the processor determines the material composition using said spectra and said transmission image. 4. The X-ray scanning system of claim 2 further comprising an array of collimated backscatter X-ray detectors for measuring energy spectra of X-rays scattered by the object at an angle greater than 90 degrees and generating backscatter data therefrom. 5. The X-ray scanning system of claim 4 wherein the processor determines the material composition using said spectra, said backscatter data, and said transmission image. 6. The X-ray scanning system of claim 1 wherein said identification of the material composition comprises at least one of determining an atomic number of at least some material in said object, determining an atomic number range of at least some material in said object, or determining an areal density of at least some material in said object. 7. The X-ray scanning system of claim 1 wherein said processor determines the material composition using said spectra by: receiving said energy spectra; normalizing said energy spectra using a value; and determining the material composition of the object based upon said normalized energy spectra and a plurality of known spectra. 8. The X-ray scanning system of claim 7 wherein said normalized energy spectra is compared to the plurality of known spectra and wherein the material composition is identified based upon said comparison. 9. The X-ray scanning system as claimed in claim 1 , wherein the X-ray beam has a pencil shape, fan shape, or conical shape. 10. The X-ray scanning system as claimed in claim 1 , wherein the X-ray source comprises at least one of a continuous X-ray source, pulsed X-ray source, intensity-modulated X-ray source, electron linear accelerator, or X-ray source having an energy level of 1 MeV or greater. 11. The X-ray scanning system of claim 1 wherein said processor determines the material composition using said spectra by: receiving said energy spectra; fitting at least one of said energy spectra to an expected energy spectrum, wherein said expected energy spectrum is at least one of a plurality of previously measured X-ray spectra generated by transmitting and detecting X-rays through known materials and correcting said detected X-rays to account for variations in detectors; and identifying the material composition of the object based upon said fitting. 12. The X-ray scanning system of claim 11 wherein said processor generates a first estimate of said material composition based on at least one of said spectra of the transmitted X-rays and not based on said fitting. 13. The X-ray scanning system of claim 11 wherein said processor identifies the material composition of the object by minimizing differences between at least one of said spectra of the transmitted X-rays and said expected energy spectrum. 14. The X-ray scanning system of claim 11 wherein each of said expected energy spectrum is specific to a particular material.