# Electron-electron attraction in an engineered electromechanical system

**Authors:** G\'abor Sz\'echenyi, Andr\'as P\'alyi, Matthias Droth

arXiv: 1703.06481 · 2017-12-11

## TL;DR

This paper proposes a theoretical model of an electromechanical system where a quantum dot coupled to a nonlinear mechanical resonator can exhibit effective electron-electron attraction, potentially enabling superconducting-like transport without superconductors.

## Contribution

It introduces a novel engineered electromechanical system demonstrating electron-electron attraction through mechanical vibrations, expanding possibilities for superconducting-like devices.

## Key findings

- Conditions for electron-electron attraction identified in a graphene-based quantum dot system.
- Potential for electronic transport via multi-electron tunneling similar to superconductors.
- System operates without the need for superconducting elements.

## Abstract

Two electrons in a quantum dot repel each other: their interaction can be characterized by a positive interaction energy. From the theory of superconductivity, we also know that mechanical vibrations of the crystal lattice can make the electron-electron interaction attractive. Analogously, if a quantum dot interacts with a mechanical degree of freedom, the effective interaction energy can be negative; that is, the electron-electron interaction might be attractive. In this work, we propose and theoretically study an engineered electromechanical system that exhibits electron-electron attraction: a quantum dot suspended on a nonlinear mechanical resonator, tuned by a bottom and a top gate electrode. We focus on the example of a dot embedded in a suspended graphene ribbon, for which we identify conditions for electron-electron attraction. Our results suggest the possibility of electronic transport via tunneling of packets of multiple electrons in such devices, similar to that in superconducting nanostructures, but without the use of any superconducting elements.

## Full text

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## Figures

4 figures with captions in the complete paper: https://tomesphere.com/paper/1703.06481/full.md

## References

43 references — full list in the complete paper: https://tomesphere.com/paper/1703.06481/full.md

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Source: https://tomesphere.com/paper/1703.06481