2017
DOI: 10.1088/1361-6528/aa53f2
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Subsurface contrast due to friction in heterodyne force microscopy

Abstract: The nondestructive imaging of subsurface structures on the nanometer scale has been a long-standing desire in both science and industry. A few impressive images were published so far that demonstrate the general feasibility by combining ultrasound with an atomic force microscope. From different excitation schemes, heterodyne force microscopy seems to be the most promising candidate delivering the highest contrast and resolution. However, the physical contrast mechanism is unknown, thereby preventing any quanti… Show more

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Cited by 13 publications
(4 citation statements)
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“…[21][22][23] In the phase image, when the phase shift is above 90 • , the force between the probe and the sample is mainly attractive, while when the phase shift is below 90 • , the force is mainly repulsive. 24 When the probe vibration was driven by the frequency, the probe had the high amplitude sensitivity, [25][26][27] but the phase sensitivity was relatively low. As shown in Figure 1, in this work, the frequency at the phase resonance peak of probe was selected for driving the probe vibration to measure the sample of spin coated photoresist 3740 (Manufactured by ALLRESIST, Germany) etched with FIB (FEI Helios G4 DualBeam), which improved the image resolution.…”
Section: Introductionmentioning
confidence: 99%
“…[21][22][23] In the phase image, when the phase shift is above 90 • , the force between the probe and the sample is mainly attractive, while when the phase shift is below 90 • , the force is mainly repulsive. 24 When the probe vibration was driven by the frequency, the probe had the high amplitude sensitivity, [25][26][27] but the phase sensitivity was relatively low. As shown in Figure 1, in this work, the frequency at the phase resonance peak of probe was selected for driving the probe vibration to measure the sample of spin coated photoresist 3740 (Manufactured by ALLRESIST, Germany) etched with FIB (FEI Helios G4 DualBeam), which improved the image resolution.…”
Section: Introductionmentioning
confidence: 99%
“…In fact, imaging buried structures with the nanometer scale resolution of scanning probe microscopy has a wide range of applications running from metrology in the semiconductor industry [7,8], to investigating processes in live cells [9]. While there has been quite some debate over the contrast mechanism(s) which enable subsurface imaging [4,6,10], elasticity (or more properly, visco-elasticity) is generally cited as the main physical cause of the contrast [2,7,[11][12][13]. Such elasticity-based subsurface AFM has shown few nanometer resolution on buried structures [14], but the depth sensitivity of this method is limited by the amount of stress that can be applied without damaging the sample.…”
Section: Introductionmentioning
confidence: 99%
“…Many research fields require a simple technique for nondestructive subsurface imaging of inorganic nanoparticles. In this respect, several advanced techniques based on ultrasound or heterodyne force detection demonstrated exceptional lateral resolution at the nanometer scale. , These techniques, implemented in some custom-built atomic force microscopes, represent significant advancements in subsurface imaging and tomography, but their use by the broader community unfortunately is hindered by added/intrinsic complexity . On the other hand, the possibility of measuring the phase of the cantilever oscillation with respect to the excitation phase at a fixed driving frequency has been implemented very early in all atomic force microscopes working in dynamic mode.…”
Section: Introductionmentioning
confidence: 99%