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Quantitative scanning capacitance microscopy analysis of two-dimensional dopant concentrations at nanoscale dimensions |
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| Authors: | A. Erickson L. Sadwick G. Neubauer J. Kopanski D. Adderton M. Rogers |
| Affiliation: | (1) Digital Instruuments, Inc., 520 E.Montecito St., 93103-3252 Santa Barbara, CA;(2) Department of Electrical Engineering, University of Utah, 84102 Salt Lake City, UT;(3) Department of Materials Technology, Intel Corporation, 95052 Santa Clara, CA;(4) Semiconductor Research Group, National Institute of Standards and Technology, 20899 Gaithersburg, MD;(5) Digital Instruments, 93103 Santa Barbara, CA |
| Abstract: | We have applied the scanning capacitance microscopy (SCM) technique of twodimensional (2-D) semiconductor dopant profiling to implanted silicon cross sections. This has permitted the first direct comparison of SCM profiling scans to secondary ion mass spectroscopy (SIMS) depth profiles. The results compare favorably in depth and several readily identifiable features of the SIMS profiles such as peak concentration and junction depth are apparent in the SCM scans at corresponding depths. The application of dopant profiling to two dimensions is possible by calibrating the SCM levels with the one-dimensional (1-D) SIMS data. Furthermore, we have subsequently simulated the SCM results with an analytic expression readily derivable from 1-D capacitance vs voltage capacitance-voltage theory. This result represents a significant breakthrough in the quantitative measurement of 2-D doping profiles. |
| Keywords: | Atomic force microscopy capacitance-voltage theory scanning capacitance microscopy two-dimensional dopant profiles |
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