Single-Layer CrI3 Grown by Molecular Beam Epitaxy

TL;DR

This study successfully demonstrates the growth of single-layer CrI3 using molecular beam epitaxy, revealing atomic structures and electronic states, and exploring temperature effects and superexchange interactions in two-dimensional magnetism.

Contribution

First report of molecular beam epitaxy growth of single-layer CrI3, providing detailed atomic and electronic structure analysis and temperature-dependent behavior.

Findings

Identified iodine trimers as basic units of the topmost I layer.

Observed different superstructures on Au(111) and graphite substrates.

Partial decomposition into chromium diiodide at 423 K.

Abstract

Single- and few-layer chromium triiodide (CrI3), which has been intensively investigated as a promising platform for two-dimensional magnetism, was usually prepared by mechanical exfoliation. Here, we report on the growth of single-layer CrI3 by molecular beam epitaxy under ultrahigh vacuum. The atomic structures and local density of states have been revealed by scanning tunneling microscopy (STM). Iodine trimers, each of which consists of three I atoms surrounding a three-fold Cr honeycomb center, have been identified as the basic units of the topmost I layer. Different superstructures of single-layer CrI3 with characteristic periodicity around 2-4 nm were obtained on Au(111), but only pristine structure was observed on graphite. At elevated temperatures (423 K), CrI3 was partially decomposed, resulting in the formation of single-layer chromium diiodide. Our bias-dependent STM images suggest that the unoccupied and occupied states are distributed spatial-separately, which is consistent with our density functional theory calculations. The effect of charge distribution on the superexchange interaction in single-layer CrI3 was discussed.