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Mapping substrate/film adhesion with contact-resonance-frequency AFM

Published

Author(s)

Donna C. Hurley, Malgorzata Kopycinska-Mueller, Eric Langlois, Tony B. Kos, Nicholas Barbosa

Abstract

We demonstrate contact-resonance-frequency atomic force microscopy (AFM) techniques to nondestructively image variations in adhesion at a substrate/film interface. Contact-resonance-frequency imaging is a dynamic AFM technique to measure the contact stiffness between the tip and the sample. Although typically used to evaluate local elastic modulus, we show here that the contact stiffness can also be used to assess another mechanical property, namely subsurface adhesion. Images were acquired on a sample containing a 20 nm gold (Au) blanket film on silicon (Si)with a 1 nm patterned interlayer of titanium (Ti). This design produced regions of very weak adhesion (Au/Si interface) and regions of strong adhesion (Au/Ti/Si). Values of the contact stiffness were 5 % lower in the regions of weak adhesion. The observed behavior is consistent with theoretical predictions for layered systems with disbonds. Our results represent progress towards quantitative measurement of adhesion parameters on the nanoscale. Such measurement capabilities have important implications for the successful development of thin-film devices, especially in emerging nanotechnology applications.
Citation
Applied Physics Letters
Volume
89

Keywords

atomic force acoustic microscopy (AFAM), contact stiffness, thin films

Citation

Hurley, D. , Kopycinska-Mueller, M. , Langlois, E. , Kos, T. and Barbosa, N. (2006), Mapping substrate/film adhesion with contact-resonance-frequency AFM, Applied Physics Letters, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=50316 (Accessed March 29, 2024)
Created July 11, 2006, Updated October 12, 2021