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7 - Instrumentation for Near-Field Scanning Microwave Microscopy

Published online by Cambridge University Press:  21 September 2017

T. Mitch Wallis
Affiliation:
National Institute of Standards and Technology, Boulder
Pavel Kabos
Affiliation:
National Institute of Standards and Technology, Boulder
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Publisher: Cambridge University Press
Print publication year: 2017

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References

Synge, E. H., “A Suggested Method for Extending Microscopic Resolution into the Ultra-microscopic Region,” Philosophical Magazine Series 7, 6, No. 35, (1928) p. 356.CrossRefGoogle Scholar
Berry, M., Wolf, E., Bloembergen, N., Erez, N., and Greenberger, D., Progress in Optics volume 50 (Elsevier, 2007) pp. 145148.Google Scholar
Bryant, C. and Gunn, J., “Noncontact Technique for the Local Measurement of Semiconductor Resistivity,” Review of Scientific Instruments 36 (1965) pp. 16141617.CrossRefGoogle Scholar
Ash, E. A. and Nicholls, G., “Super-resolution Aperture Scanning Microscope,” Nature 237 (1972) pp. 510512.CrossRefGoogle ScholarPubMed
Imtiaz, A., Wallis, T. M., and Kabos, P., “Near-field Scanning Microwave Microscopy,” IEEE Microwave Magazine 15 (2014) pp. 5264.CrossRefGoogle Scholar
Rosner, B. T. and van der Weide, D. W., “High-Frequency Near-Field Micrsocopy,” Review of Scientific Instruments 73 (2002) pp. 25052525.CrossRefGoogle Scholar
Imtiaz, A. and Anlage, S. M., “A Novel STM-Assisted Microwave Microscope with Capacitance and Loss Imaging Capability,” Ultramicroscopy 94 (2003) pp. 209216.CrossRefGoogle ScholarPubMed
Kemiktarak, U., Ndukum, T., Schwab, K. C., and Ekinci, K. L., “Radio-Frequency Scanning Tunneling Microscopy,” Nature 450 (2007) pp. 8588.CrossRefGoogle Scholar
Lee, J., Long, C. J., Yang, H.,Xiang, X.-D., and Takeuchi, I., “Atomic Resolution Imaging at 2.5 GHz Using Near-Field Microwave Microscopy,” Applied Physics Letters 97 (2010) art. no. 183111.CrossRefGoogle Scholar
Wang, Y. Q., Bettermann, A. D., and van der Weide, D. W., “Process for Scanning Near-Field Microwave Microscope Probes with Integrated Ultratall Coaxial Tips,” Journal of Vacuum Science and Technology B 25 (2007) pp. 813816.CrossRefGoogle Scholar
Talanov, V. V., Scherz, A., Moreland, R. L., and Schwarz, A. R., “A Near-Field Scanned Microwave Probe for Spatially Localized Electrical Metrology,” Applied Physics Letters 88 (2006) art. no. 134106.Google Scholar
Weber, J. C., Blanchard, P. T., Sanders, A. W., Gertsch, J. C., George, S. M., Berweger, S., Imtiaz, A., Coakley, K. J., Wallis, T. M., Bertness, K. A., Sanford, N. A., Kabos, P., and Bright, V. M., “GaN Nanowire Coated with Atomic Layer Deposition of Tungsten: A Probe for Near-Field Scanning Microwave Microscopy,” Nanotechnology 25 (2014) art. no. 415502.CrossRefGoogle ScholarPubMed
Binnig, G. and Rohrer, H., “Scanning Tunneling Microscopy,” Surface Science 126 (1983) pp. 13.CrossRefGoogle Scholar
Kochanski, G. P., “Nonlinear Alternating-Current Tunneling Microscopy,” Physical Review Letters 62 (1989) pp. 22852288.CrossRefGoogle ScholarPubMed
Martin, Y., Williams, C. C., and Wickramasinghe, H. K., “Atomic Force Microscope Force Mapping and Profiling on a Sub 100-Å Scale,” Journal of Applied Physics 61 (1987) pp. 47234729.CrossRefGoogle Scholar
Zhong, Q., Inniss, D., Kjoller, K., and Elings, V. B., “Fractured Polymer/Silica Fiber Surface Studied by Tapping Mode Atomic Force Microscopy,” Surface Science Letters 290 (1993) p. L688.CrossRefGoogle Scholar
Weber, J. C., Schlager, J. B., Sanford, N. A., Imtiaz, A., Wallis, T. M., Mansfield, L. M., Coakley, K. J., Bertness, K. A., Kabos, P., and Bright, V. M., “A Near-Field Scanning Microwave Microscope for Characterization of Inhomogeneous Photovoltaics,” Review of Scientific Instruments 83 (2012) art. no. 083702.CrossRefGoogle ScholarPubMed
Hovsepyan, A., Babajanyan, A., Sargsyan, T., Melikyan, H., Kim, S., Kim, J., Lee, K., and Friedman, B., “Direct Imaging of Photoconductivity of Solar Cells Using a Near-Field Scanning Microwave Microprobe,” Journal of Applied Physics 106 (2009) art. no. 114901.CrossRefGoogle Scholar
Tersoff, J. and Hamann, D. R., “Theory of the Scanning Tunneling Microscope,” Physical Review B 31 (1985) pp. 805813.CrossRefGoogle ScholarPubMed
Tersoff, J. and Hamann, D. R., “Theory and Application for the Scanning Tunneling Microscope,” Physical Review Letters 50 (1983) pp. 19982001.CrossRefGoogle Scholar
Bethe, H. A., “Theory of Diffraction by Small Holes,” Physical Review 66 (1944) pp. 163182.CrossRefGoogle Scholar
Farina, M., Mencarelli, D., Di Donato, A., Venanzoni, G., and Morini, A., “Calibration Protocol for Broadband Near-Field Microwave Microscopy,” IEEE Transactions on Microwave Theory and Techniques 59 (2011) pp. 27692776.CrossRefGoogle Scholar
Imtiaz, A., Quantitative Materials Contrast at High Spatial Resolution with a Novel Near-Field Scanning Microwave Microscope, Ph.D. Dissertation, University of Maryland (2005).CrossRefGoogle Scholar
Steinhauer, D. E., Vlahacos, C. P., Dutta, S. K., Wellstood, F. C., and Anlage, S. M., “Surface Resistance Imaging with a Scanning Near-Field Microwave Microscope,” Applied Physics Letters 71 (1997) pp. 17461738.CrossRefGoogle Scholar
Steinhauer, D. E., Vlahacos, C. P., Dutta, S. K., Feenstra, B. J., Wellstood, F. C., and Anlage, S. M., “Quantitative Imaging of Sheet Resistance with a Scanning Near-Field Microwave Microscope,” Applied Physics Letters 72 (1998) pp. 861863.CrossRefGoogle Scholar
Gao, C. and Xiang, X.-D., “Quantitative Microwave Near-Field Microscopy of Dielectric Properties,” Review of Scientific Instruments 69 (1998) pp. 38463851.CrossRefGoogle Scholar
Gregory, A. P., Blackburn, J. F., Lees, K., Clarke, R. N., Hodgetts, T. E., Hanham, S. M., and Klein, N., “A Near-Field Scanning Microwave Microscope for Measurement of the Permittivity and Loss of High-Loss Materials,” 2014 84th ARFTG Microwave Measurement Symposium (2014) pp. 18.Google Scholar
Kim, J., Lee, K., Friedman, B., and Cha, D., “Near-Field Scanning Microwave Microscopy Using a Dielectric Resonator,” Applied Physics Letters 83 (2003) pp. 10321034.CrossRefGoogle Scholar
Gao, C., Wei, T., Duewer, F., Lu, Y., and Xiang, X.-D., “High Spatial Resolution Quantitative Microwave Impedance Microscopy by a Scanning Tip Microwave Near-Field Microscope,” Applied Physics Letters 71 (1997) pp. 18721874.CrossRefGoogle Scholar
Tabib-Azar, M., Su, D.-P., Pohar, A., LeClair, S. R., and Ponchak, G., “0.4 µm Spatial Resolution with 1 GHz (l = 30 cm) Evanescent Microwave Probe,” Review of Scientific Instruments 70 (1999) pp. 17251729.CrossRefGoogle Scholar
Imtiaz, A., Wallis, T. M., Lim, S.-H., Tanbakuchi, H., Huber, H.-P., Hornung, A., Hinterdorfer, P., Smoliner, J., Kienberger, F., and Kabos, P., “Frequency-Selective Contrast on Variably Doped p-type Silicon with a Scanning Microwave Microscope,” Journal of Applied Physics 111 (2012) art. no. 093727.CrossRefGoogle Scholar
Kodera, N., Yamamoto, D., Ishikawa, R., and Ando, T., “Video Imaging of Walking Myosin V by High-Speed Atomic Force Microscopy,” Nature 468 (2010) pp. 7276.CrossRefGoogle ScholarPubMed
Tselev, A., Velmurugan, J., Ievlev, A.V., Kalinin, S.V. and Kolmakov, A., “Seeing through Walls at the Nanoscale: Microwave Microscopy of Enclosed Objects and Processes in Liquids,” ACS Nano 10 (2016) pp. 35623570.CrossRefGoogle Scholar

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