| AVS 59th Annual International Symposium and Exhibition | |
| Electron Transport at the Nanoscale Focus Topic | Friday Sessions |
| Session ET+SS+GR+SP-FrM |
| Session: | Electron Transport at the Nanoscale: Development of Theories and Techniques |
| Presenter: | P. Jelinek, Institute of Physics of ASCR, Czech Republic |
| Authors: | P. Jelinek, Institute of Physics of ASCR, Czech Republic M. Ondracek, Institute of Physics of ASCR, Czech Republic F. Flores, Universidad Autonoma de Madrid, Spain |
| Correspondent: | Click to Email |
Recent progress has allowed merging AFM and STM into a new experimental setup where tunneling current and atomic forces are recorded simultaneously. The possibility to collect both quantities simultaneously opens new horizons not only in advanced characterization at the atomic scale but also in understanding fundamental relations between the electron transfer and formation of the chemical bond between two bodies.
Actually, there is a long-standing debate in the scientific community about the relation between the chemical force and the tunneling current (see e.g. [1]) on the atomic scale. Both the tunneling current and the short-range component of the force, induced by the formation of the chemical bond, exhibit in atomic contacts an exponential decay with increasing distance in the range of several angstroms. As the quantities depend directly on the wave-function overlap between outermost atoms of tip and surface, the corresponding exponential functions should have similar characteristic decay length. In particular, the relation between the chemical force F and the tunneling current I follows the law Fn~I, where n is an integer number. Over the last 10 years, several different scaling factors n, varying from 1 to 4, have been proposed by different groups based on both theoretical analysis and experimental measurements (see reference in [2]); still there is no consensus on the relation between the chemical force and the tunneling current.
In this contribution, we explain the relation between the tunneling current and the interaction force at the atomic scale using a simple analytical model [2]. The model unveils the existence of two characteristic scaling regimes, where the tunneling current is either proportional to the chemical force I~F or to the square of the chemical force, i.e. I~F2. We show that the existence of a given regime is basically controlled by two parameters: (i) the electronic level degeneracy and (ii) the hopping between electronic levels involved in the interaction process. Finally, we will collate our theoretical prediction with experimental AFM/STM measurements of single-atom point contacts and complex DFT simulations [3] to confirm the existence of these two characteristic regimes.
[1] W. Hofer and A.J. Fisher, Phys. Rev. Lett. 91, 036803 (2003) and the reply in by C.J. Chen
[2] P. Jelinek et al, J. Cond. Mat. Phys. 24, 084001 (2012).
[3] M. Ternes et al Phys. Rev. Lett. 106, 016802 (2011).