Atomic scale variation of electron tunneling into a Luttinger liquid ? : High resolution scanning tunneling spectroscopy study on Au/Ge(001)

TL;DR

This study uses high-resolution scanning tunneling spectroscopy to investigate Au/Ge(001) atomic wires, finding no evidence of a Tomonaga-Luttinger liquid state and highlighting the impact of defects on tunneling spectra.

Contribution

It provides a detailed STS analysis showing the absence of TLL behavior in Au/Ge(001) wires and emphasizes the importance of defect-free 1D systems for TLL studies.

Findings

No evidence of 1D metallic channels in local density-of-states maps.

Tunneling spectra deviate from power-law behavior expected for TLL.

Defects significantly influence the tunneling spectra near the Fermi level.

Abstract

Au-induced atomic wires on the Ge(001) surface were recently claimed to be an ideal 1D metal and their tunneling spectra were analyzed as the manifestation of a Tomonaga-Luttinger liquid (TLL) state. We reinvestigate this system for atomically well-ordered areas of the surface with high resolution scanning tunneling microscopy and spectroscopy (STS). The local density-of-states maps do not provide any evidence of a metallic 1D electron channel along the wires. Moreover, the atomically resolved tunneling spectra near the Fermi energy are dominated by local density-of-states features, deviating qualitatively from the power-law behavior. On the other hand, the defects strongly affect the tunneling spectra near the Fermi level. These results do not support the possibility of a TLL state for this system. An 1D metallic system with well-defined 1D bands and without defects are required for the STS study of a TLL state.