The quantitative analysis of thin specimens: a review of progress from the Cliff-Lorimer to the new ζ-factor methods |
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Authors: | M. WATANABE,& D. B. WILLIAMS |
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Affiliation: | Department of Materials Science and Engineering/Center for Advanced Materials and Nanotechnology, Lehigh University, Bethlehem, PA 18015, U.S.A. |
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Abstract: | A new quantitative thin‐film X‐ray analysis procedure termed the ζ‐factor method is proposed. This new ζ‐factor method overcomes the two major limitations of the conventional Cliff‐Lorimer method for quantification: (1) use of pure‐element rather than multielement, thin‐specimen standards and (2) built‐in X‐ray absorption correction with simultaneous thickness determination. Combined with a universal, standard, thin specimen, a series of ζ‐factors covering a significant fraction of the periodic table can be estimated. This ζ‐factor estimation can also provide information about both the detector efficiency and the microscope–detector interface system. Light‐element analysis can also be performed more easily because of the built‐in absorption correction. Additionally, the new ζ‐factor method has several advantages over the Cliff‐Lorimer ratio method because information on the specimen thickness at the individual analysis points is produced simultaneously with compositions, thus permitting concurrent determination of the spatial resolution and the analytical sensitivity. In this work, details of the ζ‐factor method and how it improves on the Cliff‐Lorimer approach are demonstrated, along with several applications. |
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Keywords: | Absorption correction Cliff-Lorimer ratio technique detector efficiency light-element analysis minimum detectable mass minimum mass fraction pure-element thin-film standard quantitative thin-film X-ray analysis spatial resolution thickness determination ζ (zeta)-factor method |
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