Modelling atomic scale manipulation with the non-contact atomic force microscope

Trevethan, T. and Watkins, Matthew and Kantorovich, L. N. and Shluger, A. L. and Polesel-Maris, J. and Gauthier, S. (2006) Modelling atomic scale manipulation with the non-contact atomic force microscope. Nanotechnology, 17 (23). pp. 5866-5874. ISSN 0957-4484

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Item Type:Article
Item Status:Live Archive

Abstract

We present the results of calculations performed to model the process of lateral manipulation of an oxygen vacancy in the MgO(001) surface using the non-contact atomic force microscope (NC-AFM). The potential energy surfaces for the manipulation as a function of tip position are determined from atomistic modelling of the MgO(001) surface interacting with a Mg terminated MgO tip. These energies are then used to model the dynamical evolution of the system as the tip oscillates and at a finite temperature using a kinetic Monte Carlo method. The manipulation process is strongly dependent on the lateral position of the tip and the system temperature. It is also found that the expectation value of the point at which the vacancy jumps depends on the trajectory of the oscillating cantilever as the surface is approached. The effect of the manipulation on the operation of the NC-AFM is modelled with a virtual dynamic AFM, which explicitly simulates the entire experimental instrumentation and control loops. We show how measurable experimental signals can result from a single controlled atomic scale event and suggest the most favourable conditions for achieving successful atomic scale manipulation experimentally. © 2006 IOP Publishing Ltd.

Keywords:Atomic force microscopy, Computer simulation, Crystalline materials, Magnesia, Mathematical models, Monte Carlo methods, Potential energy, Surface phenomena, Atomic scale manipulation, Atomistic modelling, Oscillating cantilevers, Nanotechnology
Subjects:F Physical Sciences > F200 Materials Science
H Engineering > H820 Atomic Engineering
Divisions:College of Science > School of Mathematics and Physics
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ID Code:17723
Deposited On:14 Aug 2015 07:53

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