Two-dimensional TiOx nanostructures on Au(111): a Scanning Tunneling Microscopy and Spectroscopy investigation

TL;DR

This study characterizes five distinct two-dimensional titanium oxide nanostructures on Au(111) using STM, STS, LEED, and DFT, revealing their structural, electronic, and growth properties with implications for surface science.

Contribution

It provides a detailed experimental and theoretical analysis of TiOx phases on Au(111), identifying their structures and electronic behaviors for the first time.

Findings

Identified five TiOx phases with distinct morphologies.

Supported a $(2\times 2)$ Ti-O bilayer model for honeycomb structure.

Observed partial metallization and semiconducting behavior in different phases.

Abstract

We investigated the growth of titanium oxide two-dimensional (2D) nanostructures on Au(111), produced by Ti evaporation and post-deposition oxidation. Scanning tunneling microscopy and spectroscopy (STM and STS) and low-energy electron diffraction (LEED) measurements characterized the morphological, structural and electronic properties of the observed structures. Five distinct TiO\sub{x} phases were identified: the \emph{honeycomb} and \emph{pinwheel} phases appear as monolayer films wetting the gold surface, while nanocrystallites of the \emph{triangular}, \emph{row} and \emph{needle} phases grow mainly over the honeycomb or pinwheel layers. Density Functional Theory (DFT) investigation of the honeycomb structure supports a $(2\times 2)$ structural model based on a Ti-O bilayer having $\text{Ti}_2\text{O}_3$ stoichiometry. The pinwheel phase was observed to evolve, for increasing coverage, from single triangular crystallites to a well-ordered film forming a $(4\sqrt{7}\times 4\sqrt{7})R19.1^\circ$ superstructure, which can be interpreted within a moir\~A\c{opyright}-like model. Structural characteristics of the other three phases were disclosed from the analysis of high-resolution STM measurements. STS measurements revealed a partial metallization of honeycomb and pinwheel and a semiconducting character of row and triangular phases.