The theory of magneto-transport in quantum dots: 3D-0D and 2D-0D tunnelling and selection rules for the angular momentum

TL;DR

This paper models magneto-transport in quantum dots, revealing how magnetic fields influence tunnelling amplitudes and angular momentum selection rules, enabling detailed analysis of quantum dot wavefunctions and novel magnetic field effects.

Contribution

It introduces a model analyzing tunnelling from bulk and 2D layers, demonstrating magnetic field effects on tunnelling amplitudes and angular momentum selection rules in quantum dots.

Findings

Oscillations in current resonance amplitudes with magnetic field

Magnetic field-dependent suppression of tunnelling based on angular momentum

Predicted enhancement of resonant features from 2D layers under magnetic field

Abstract

A study of magneto-transport through quantum dots is presented. The model allows to analyze tunnelling both from bulk-like contacts and from 2D accumulation layers. The fine features in the I-V characteristics due to the quantum dot states are known to be shifted to different voltages depending upon the value of the magnetic field. While this effect is also well reproduced by our calculations, in this work we concentrate on the amplitude of each current resonance as a function of the magnetic field. Such amplitudes show oscillations reflecting the variation of the density of states at the Fermi energy in the emitter. Furthermore the amplitude increases as a function of the magnetic field for certain features while it decreases for others. In particular we demonstrate that the behaviour of the amplitude of the current resonances is linked to the value of the angular momentum of each dot level through which tunnelling occurs. We show that a selection rule on the angular momentum must be satisfied. As a consequence, tunnelling through specific dot states is strongly suppresses and sometimes prohibited altogether by the presence of the magnetic field. This will allow to extract from the experimental curves detailed information on the nature of the quantum dot wavefunctions involved in the electronic transport. Furthermore, when tunnelling occurs from a 2D accumulation layer to the quantum dot, the presence of a magnetic field hugely increases the strength of some resonant features. This effect is predicted by our model and, to the best of our knowledge, has never been observed.