Direct Measurement of the Spin-Orbit Interaction in a Two-Electron InAs Nanowire Quantum Dot

TL;DR

This paper reports a direct measurement of spin-orbit interaction strength in a two-electron InAs nanowire quantum dot, revealing a significant avoided crossing caused by spin-orbit coupling.

Contribution

The study introduces a straightforward method to quantify spin-orbit interaction in two-electron quantum dots with strong spin-orbit coupling.

Findings

Measured spin-orbit coupling induces an avoided crossing of 0.25 meV.

Determined the spin-orbit length to be approximately 127 nm.

Observed the dominance of Zeeman energy over orbital effects in the singlet-triplet transition.

Abstract

We demonstrate control of the electron number down to the last electron in tunable few-electron quantum dots defined in catalytically grown InAs nanowires. Using low temperature transport spectroscopy in the Coulomb blockade regime we propose a simple method to directly determine the magnitude of the spin-orbit interaction in a two-electron artificial atom with strong spin-orbit coupling. Due to a large effective g-factor |g*|=8+/-1 the transition from singlet S to triplet T+ groundstate with increasing magnetic field is dominated by the Zeeman energy rather than by orbital effects. We find that the spin-orbit coupling mixes the T+ and S states and thus induces an avoided crossing with magnitude $\Delta_{SO}$=0.25+/-0.05 meV. This allows us to calculate the spin-orbit length $\lambda_{SO}\approx$127 nm in such systems using a simple model.