Open AccessFrequency shift, damping, and tunneling current coupling with quartz tuning forks in noncontact atomic force microscopy
Author(s) -
Laurent y,
Franck Bocquet,
Franck Para,
Christian Loppacher
Publication year - 2016
Publication title -
physical review. b./physical review. b
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.78
H-Index - 465
eISSN - 2469-9969
pISSN - 2469-9950
DOI - 10.1103/physrevb.94.115421
Subject(s) - coupling (piping) , tuning fork , quantum tunnelling , physics , piezoelectricity , scanning tunneling microscope , electrode , quartz , field (mathematics) , atomic force microscopy , current (fluid) , condensed matter physics , materials science , acoustics , vibration , nanotechnology , quantum mechanics , composite material , metallurgy , thermodynamics , mathematics , pure mathematics
International audienceA combined experimental and theoretical approach to the coupling between frequency-shift (Delta f), damping, and tunneling current (I-t) in combined noncontact atomic force microscopy/scanning tunneling microscopy using quartz tuning forks (QTF)-based probes is reported. When brought into oscillating tunneling conditions, the tip located at the QTF prong's end radiates an electromagnetic field which couples to the QTF prong motion via its piezoelectric tensor and loads its electrodes by induction. Our approach explains how those I-t-related effects ultimately modify the Delta f and the damping measurements. This paradigm to the origin of the coupling between I-t and the nc-AFM regular signals relies on both the intrinsic piezoelectric nature of the quartz constituting the QTF and its electrodes design
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