The One-Dimensional Wigner Crystal in Carbon Nanotubes

TL;DR

This paper demonstrates the experimental realization of a one-dimensional Wigner crystal in low-disorder carbon nanotubes, revealing strong electron correlations and potential for quantum computing applications.

Contribution

It provides the first unambiguous experimental evidence of a 1D Wigner crystal in carbon nanotubes using low-temperature transport spectroscopy.

Findings

Observation of Wigner crystal formation in carbon nanotubes

Identification of unique spin and magnetic properties

Potential for quantum computing with long coherence times

Abstract

Electron-electron interactions strongly affect the behavior of low-dimensional systems. In one dimension (1D), arbitrarily weak interactions qualitatively alter the ground state producing a Luttinger liquid (LL) which has now been observed in a number of experimental systems. Interactions are even more important at low carrier density, and in the limit when the long-ranged Coulomb potential is the dominant energy scale, the electron liquid is expected to become a periodically ordered solid known as the Wigner crystal. In 1D, the Wigner crystal has been predicted to exhibit novel spin and magnetic properties not present in an ordinary LL. However, despite recent progress in coupled quantum wires, unambiguous experimental demonstration of this state has not been possible due to the role of disorder. Here, we demonstrate using low-temperature single-electron transport spectroscopy that a hole gas in low-disorder carbon nanotubes with a band gap is a realization of the 1D Wigner crystal. Our observation can lead to unprecedented control over the behavior of the spatially separated system of carriers, and could be used to realize solid state quantum computing with long coherence times.