Patent Number: 
Section: claims

1. A method for determining a material composition for a thin film layer in a test sample, the method comprising:applying an electron probe microanalysis (EPMA) operation to the thin film layer to generate a set of characteristic x-rays; andgenerating an output value for the material composition based on the set of characteristic x-rays and a measured thickness value for a test layer in the test sample,wherein the test layer is the thin film layer, wherein the material composition is material phase, and wherein generating the output value comprises:identifying a first one of a plurality of trial phases for the thin film layer defining an expected composition that is substantially consistent with a calculated composition, the expected composition being based on the first one of the plurality of trial phases, a density for the test layer defined by the first one of the plurality of trial phases, and the measured thickness value for the test layer, and the calculated composition being based on the set of characteristic x-rays, the measured thickness value for the thin film layer, and the density for the test layer; andproviding the first one of the plurality of trial phases as the output value. 2. The method of claim 1, wherein identifying the first one of the plurality of trial phases comprises:selecting a test one of the plurality of trial phases;determining a density for the test one of the plurality of trial phases;deriving an expected composition for the test one of the plurality of trial phases based on the density and the measured thickness value, and the test one of the plurality of trial phases;comparing the expected composition of the test one of the plurality of trial phases to a calculated composition of the test one of the plurality of trial phases, the calculated composition of the test one of the plurality of trial phases being derived from the set of characteristic x-rays, the measured thickness value, and the density;repeating the steps of selecting, determining, deriving, and comparing until the expected composition for the test one of the plurality of trial phases is consistent with the calculated composition of the test one of the plurality trial phases; andassigning the test one of the plurality of trial phases as the first one of the plurality of trial phases. 3. The method of claim 2, wherein identifying the first one of the plurality of trial phases further comprises updating the measured thickness value according to the test one of the plurality of trial phases. 4. The method of claim 1, wherein identifying the first one of the plurality of trial phases comprises:generating a set of expected compositions for the plurality of trial phases, each of the set of expected compositions being determined by one of the plurality trial phases, a density defined by the one of the plurality of trial phases and the measured thickness value;generating a set of calculated compositions for the plurality of trial phases, each of the set of calculated compositions being determined by the set of characteristic x-rays, the measured thickness value, and the density defined by the one of the plurality of trial phases;comparing each of the set of expected compositions for the plurality of trial phases to an associated one of the set of expected compositions for the plurality of trial phases to determine the first one of the plurality of trial phases. 5. The method of claim 4, wherein generating a set of expected compositions for the plurality of trial phases comprises adjusting the measured thickness value based on the one of the plurality of trial phases, andwherein generating a set of calculated compositions for the plurality of trial phases comprises adjusting the measured thickness value based on the one of the plurality of trial phases. 6. The method of claim 1, wherein the thin film layer comprises one of a silicide layer formed over a single crystalline silicon substrate, a phosphorous-doped polysilicon layer formed over the single crystalline silicon substrate, a silicon germanium boron layer formed over the single crystalline silicon substrate, and a silicon oxy-nitride layer formed over the single crystalline silicon substrate. 7. An electron probe microanalysis (EPMA) tool comprising:an e-beam generator for directing an e-beam at a test sample, the test sample comprising a thin film formed on a substrate;an x-ray detector for measuring a set of characteristic x-rays generated by the test sample in response to the e-beam; andmaterial composition determination logic for determining a material composition of the thin film, the material composition determination logic comprising:compilation logic for compiling measured thickness data for a test layer in the test sample and the set of characteristic x-rays; andanalysis logic for determining a material composition for the thin film based on the measured thickness data for the test layer and the set of characteristic x-rays,wherein the test layer is the thin film, and wherein the analysis logic comprises:logic for identifying a first one of a plurality of trial phases for the thin film, the first one of the plurality of trial phases defining an expected composition that is substantially consistent with a calculated composition for the first one of the plurality of trial phases; andlogic for providing the first one of the set of trial phases as the material phase of the thin film,wherein the expected composition is based on the first one of the plurality of trial phases, a density for the test layer defined by the first one of the plurality of trial phases, and the measured thickness data for the test layer, andwherein the calculated composition for the first one of the plurality of trial phases is based on the set of characteristic x-rays, the density, and the measured thickness data for the test layer. 8. The EPMA tool of claim 7, wherein the logic for identifying the first one of the plurality of trial phases comprises:logic for selecting a test one of the plurality of trial phases;logic determining a density for the test one of the plurality of trial phases;logic for generating an expected composition for the test one of the plurality of trial phases based on the density, the measured thickness data for the test layer, and the test one of the plurality of trial phases;logic for comparing the expected composition of the test one of the plurality of trial phases with a calculated composition of the test one of the plurality of trial phases, the calculated composition of the test one of the plurality of trial phases being derived from the set of characteristic x-rays, the measured thickness data for the test layer, and the density;logic for repeatedly applying the logic for selecting, the logic for determining, the logic for generating, and the logic for comparing until the expected composition of the test one of the plurality of trial phases is consistent with the calculated composition of the test one of the plurality of trial phases; andlogic for assigning the test one of the plurality of trial phases as the first one of the plurality of trial phases. 9. The EPMA tool of claim 7, further comprising a material phase database for providing the set of trial phases. 10. The EPMA tool of claim 7, further comprising a communications interface for receiving at least one of the set of trial phases and the thickness of the thin film. 11. The EPMA tool of claim 7, wherein the thin film comprises one of a silicide layer formed over a single crystalline silicon substrate and a phosphorous-doped polysilicon layer formed over the single crystalline silicon substrate. 12. A system for determining a material composition of a thin film in a test sample, the system comprising:means for compiling a set of characteristic material data generated by directing a probe beam at the thin film, the means for compiling the set of characteristic material data comprising an electron probe microanalysis module;means for compiling measured thickness data for a test layer in the test sample; andmeans for determining the material composition using the set of characteristic material data and the measured thickness data,wherein the test layer comprises the thin film, andwherein the means for determining the material composition comprises:means for identifying a first one of a plurality of trial phases for the thin film layer, the first one of the plurality of trial phases defining an expected composition that is substantially consistent with a calculated composition for the first one of the plurality of trial phases; andproviding the first one of the plurality of phases as the material composition,wherein the expected composition is based on the first one of the plurality of trial phases, a density for the test layer defined by the first one of the plurality of trial phases, and the measured thickness data for the test layer, andwherein the calculated composition for the first one of the plurality of trial phases is based on the set of characteristic material data, the density, and the measured thickness data for the test layer. 13. The system of claim 12, further comprising means for accessing a material phase database to compile the set of trial phases. 14. The system of claim 12,wherein the probe beam comprises an e-beam, andwherein the set of characteristic material data comprises a set of characteristic x-rays. 15. The system of claim 12, further comprising means for performing optical metrology on the test sample to generate the measured thickness data for the test layer.