7/1/2023 0 Comments Piezoelectric tuning fork![]() ![]() Cleveland, et al., A nondestructive method for determining the spring constant of cantilevers for scanning force microscopy. Rychen, et al., Force–distance studies with piezoelectric tuning forks below 4.2 K. Rubio-Bollinger, Force-gradient-induced mechanical dissipation of quartz tuning fork force sensors used in atomic force microscopy. Low-temperature high-resolution magnetic force microscopy using a quartz tuning fork. W.Rensen, et al., Atomic steps with tuning-fork-based noncontact atomic force microscopy. Grober, et al., Fundamental limits to force detection using quartz tuning forks. Reifenberger, Measuring the interaction force between a tip and a substrate using a quartz tuning fork under ambient conditions. Rust, Recipes for cantilever parameter determination in dynamic force spectroscopy: spring constant and amplitude. Reifenberger, Calibrating a tuning fork for use as a scanning probe microscope force sensor. Liu, et al., A simple and accurate method for calibrating the oscillation amplitude of tuning-fork based AFM sensors. Hayashi, et al., Evaluation of tuning fork type force transducer for use as a transfer standard. Rubio-Bollinger, Dynamics of quartz tuning fork force sensors used in scanning probe microscopy. Le Sueur, et al., Phase controlled superconducting proximity effect probed by tunneling spectroscopy. Smit, et al., A low temperature scanning tunneling microscope for electronic and force spectroscopy. Rubio-Bollinger, Carbon fibre tips for scanning probe microscopy based on quartz tuning fork force sensors. thesis, Eidgenössische Technische Hochschule Zürich (2001) Rychen, Combined low-temperature scanning probe microscopy and magneto-transport experiments for the local investigation of mesoscopic sysmtems. Giessibl, A direct method to calculate tip–sample forces from frequency shifts in frequency-modulation atomic force microscopy. Giessibl, High-speed force sensor for force microscopy and profilometry utilizing a quartz tuning fork. Frequency modulation detection using high-Q cantilevers for enhanced force microscope sensitivity. Operation characteristics of piezoelectric quartz tuning forks in high magnetic fields at liquid helium temperatures. The force needed to move an atom on a surface. Agrait, Metallic adhesion in atomic-size junctions. Giessibl, et al., Subatomic features on the silicon (111)-(7 ×7) surface observed by atomic force microscopy. Mannhart, Friction traced to the single atom. Grober, Piezoelectric tip-sample distance control for near-field optical microscopes. This process is experimental and the keywords may be updated as the learning algorithm improves. These keywords were added by machine and not by the authors. The fabrication and the characterization of these carbon fiber tips as well as their performance in STM/AFM will be detailed. The remarkable electrical and mechanical properties of carbon fiber make these tips more suitable for combined and/or simultaneous STM and AFM than conventional metallic tips. In the second one, we will present an implementation of a quartz tuning fork supplemented with optimized tips based on carbon fibers. Relevant parameters for the tuning fork performance such as the effective spring constant can be obtained from our analysis. We will also show that a coupled harmonic oscillators model, which includes a finite coupling between the prongs, is in remarkable agreement with the observed motion of the tuning forks. In the first one, we will show a detailed analysis of the dynamics of quartz tuning fork resonators which are being increasingly used in scanning probe microscopy as force sensors. This chapter will be divided in two main parts. ![]()
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