Patent Number: 
Section: claims

1. An apparatus for measuring film stack characteristics of a sample, the apparatus comprising: a beam generator configurable to direct an electron beam towards the sample such that the electron beam completely penetrates a plurality of desired layers of the film stack, the electron beam causing X-rays to emanate from the sample;  at least a first and a second wavelength dispersive X-ray detector positioned above the sample wherein each detector detects X-rays about a different characteristic emission level, wherein the first detector is configured to detect X-rays having characteristic emission levels for a top layer of the film stack and the second detector is configured to detect X-rays having characteristic emission levels for an underlying layer that lies beneath the top layer, whereby material characteristics of the desired layers can be measured simultaneously; and  an analysis unit that collects data resulting from the detected X-rays, wherein the data that is collected is raw data, the analysis unit also configured to compare predicted data derived from one or more equations that model the film stack against the raw data. 2. The apparatus as recited in  claim 1  wherein the first X-ray detector is configured to detect X-rays of a specific energy level. claim 1 3. The apparatus as recited in  claim 1  wherein the wavelength dispersive system contains a reflective surface and a sensor, the reflective surface configured to direct X-rays of a predetermined energy level to the sensor. claim 1 4. The apparatus as recited in  claim 1  further comprising a processor linked to the beam generator and to the first X-ray detector. claim 1 5. The apparatus as recited in  claim 4  wherein the processor is configured to control the first X-ray detector so that it detects X-rays of a specific energy level. claim 4 6. The apparatus as recited in  claim 4  wherein the processor is configured to control the beam generator so that the electron beam directed to the sample penetrates at least a conductive film layer and a liner film layer of the sample. claim 4 7. An apparatus as recited in  claim 1  wherein each of the characteristic emission levels correspond to a different layer of the film stack. claim 1 8. An apparatus as recited in  claim 1  wherein the electron beam completely penetrates the top and the underlying layers of the film stack so that the thickness of the top and the underlying layers can be determined. claim 1 9. An apparatus as recited in  claim 1  wherein the electron beam completely penetrates at least a conductive film layer and a liner film layer of the sample. claim 1 10. An apparatus as recited in  claim 1  wherein the electron beam is set at a substantially constant voltage level. claim 1 11. The method of determining film stack characteristic values as recited in  claim 10  further comprising recording the set of estimated film stack characteristic values when a difference between the predicted data and the raw data is equal to or smaller than the predetermined margin of error, wherein the estimated film stack characteristic values are an acceptable estimate of the film stack""s characteristic. claim 10 12. A method for measuring at least one characteristic of a film stack on a sample, the method comprising: directing a charged particle beam towards the sample such that the charged particle beam completely penetrates at least two layers of the film stack, the charged particle beam causing X-rays to emanate from the sample;  detecting X-rays at a first characteristic emission level that represents an emission level for a top layer of the film stack using at least a first wavelength dispersive X-ray detector that is positioned above the sample;  detecting X-rays at a second characteristic emission level that represents an emission level for an underlying layer of the film stack using at least a second wavlength dispersive X-ray detector that is positioned above the sample, the underlying layer being a layer of material underneath the top layer;  collecting data resulting from the detected X-rays, wherein the data that is collected is raw data; and  comparing predicted data derived from one or more equations that model the film stack against the raw data. 13. The method for measuring as recited in  claim 12 , further comprising configuring the first X-ray detector to detect X-rays of a specific energy level. claim 12 14. The method for measuring as recited in  claim 12  further comprising positioning a reflective surface contained within the wavelength dispersive system in an orientation to direct X-rays of a predetermined energy level to a sensor contained within the wavelength dispersive system. claim 12 15. The method for measuring as recited in  claim 12 , the method further comprising selecting a charged particle beam energy and a charged particle beam current at which the charged particle beam will be produced. claim 12 16. The method for measuring as recited in  claim 12  wherein a conductive film layer and a liner film layer are two of the at least two layers that are penetrated by the charged particle beam. claim 12 17. The method of determining film stack characteristic values as recited in  claim 12  wherein the raw and predicted data represent a count value of X-rays having a specific energy level, the count value being the total number of X-rays received by each of the wavelength dispersive systems over a period of time. claim 12 18. A method as recited in  claim 12  wherein each of the characteristic emission levels correspond to a different layer of the film stack. claim 12 19. A method as recited in  claim 12  wherein the charged particle beam completely penetrates the thickness of the top and the underlying layers of the film stack so that the thickness of the top and the underlying layers are determined. claim 12 20. An apparatus for measuring the thickness of two or more layers within a film stack sample, the apparatus comprising: a beam generator configurable to direct an electron beam towards the sample such that the electron beam completely penetrates at least two layers of the film stack, the electron beam causing X-rays to emanate from the sample;  at least a first and a second wavelength dispersive X-ray detector positioned above the sample wherein each detector is configured to detect a respective portion of the X-rays emanating from the sample, whereby material characteristics of the at least two layers can be measured simultaneously; and  an analysis unit that collects data resulting from the detected X-rays, wherein the data that is collected is raw data, the analysis unit also configured to compare predicted data derived from one or more equations that model the film stack against the raw data. 21. An apparatus as recited in  claim 20  wherein the first X-ray detector is configured to detect X-rays of a specific energy level. claim 20 22. An apparatus as recited in  claim 20  wherein the first X-ray detector is a wavelength dispersive system. claim 20 23. An apparatus as recited in  claim 22  wherein the wavelength dispersive system contains a reflective surface and a sensor, the reflective surface configured to direct X-rays of a predetermined energy level to the sensor. claim 22 24. An apparatus as recited in  claim 20  further comprising a second X-ray detector, wherein the first and second X-ray detectors are wavelength dispersive systems. claim 20 25. A method for measuring as recited in  claim 12 , further comprising: claim 12 selecting a set of estimated film stack characteristic values; and  obtaining the predicted data by solving the one or more equations that model the film stack using the set of estimated film stack characteristic values. 26. A method for measuring as recited in  claim 25 , further comprising: claim 25 selecting a new set of estimated film stack characteristic values when a difference between the predicted data and the raw data is larger than a predetermined margin of error; and  obtaining a new set of predicted data by solving equations which model the film stack using the new set of estimated film stack characteristic values when the difference between the predicted data and the raw data is larger than the predetermined margin of error. 27. An apparatus as recited in  claim 20  wherein the electron beam can be scanned over the film stack sample in a scan pattern. claim 20 28. An apparatus as recited in  claim 27  further comprising: claim 27 an octupole for aligning the electron beam generated by the beam generator; and  a lower quadrupole for further adjusting the alignment of the electron beam.