# Atomic-Scale Engineering of Ge–Sb–Te Compounds: Ge Vacancies in Bulk GeSb4Te7 and Layer Sliding in GeSb2Te4 Monolayers

**Authors:** Ruslan M. Meftakhutdinov, Renat T. Sibatov, Vyacheslav V. Svetukhin

PMC · DOI: 10.3390/nano16050292 · 2026-02-26

## TL;DR

This paper explores how atomic-scale defects and structures in Ge–Sb–Te compounds affect their electronic and optical properties, important for memory and photonics applications.

## Contribution

The study reveals how Ge vacancies and layer sliding in GeSb4Te7 and GeSb2Te4 influence electronic and optical properties through density functional theory calculations.

## Key findings

- Ge vacancies in GeSb4Te7 reduce p-type degeneracy and widen the band gap from 0.47 to 0.67 eV.
- Layer sliding in GeSb2Te4 monolayers causes a semiconductor-to-metal transition and changes in optical absorption.
- Asymmetric energy barriers in monolayers suggest favorable reversible switching via structural distortions.

## Abstract

Phase-change materials of the Ge–Sb–Te (GST) system are promising for non-volatile memory and programmable photonics owing to their reversible amorphous–crystalline transitions. Among these materials, GeSb4Te7 stands out for its optimal balance of thermal stability, switching speed, and energy efficiency. The properties of GST materials are critically dependent on structural defects, particularly germanium vacancies that occur during synthesis and operation. Using density functional theory, we demonstrate that Ge vacancies and Ge–Sb intermixing significantly influence the electronic and optical properties of GeSb4Te7. Positive binding energies reveal vacancy clustering tendencies, which systematically reduce p-type degeneracy and widen the band gap (from 0.47 to 0.67 eV at a 2.7% vacancy concentration). Consequently, the metallic optical response in the visible range diminishes, as reflected in the less negative real dielectric function. Furthermore, we extend our investigation to the fundamental building block of this material system, the GeSb2Te4 monolayer. By studying controlled interlayer displacements of Ge and Te atoms in an otherwise stoichiometric slab, we elucidate the switching mechanism in the two-dimensional limit. The pristine monolayer exhibits semiconducting behavior with an indirect band gap of 0.74 eV, while layer sliding induces a semiconductor-to-metal transition accompanied by pronounced changes in the optical absorption spectrum. The asymmetric energy barrier (1.69 eV forward, 0.60 eV reverse) suggests favorable reversible switching via structural distortions alone, without requiring chemical modifications. The obtained results, spanning from defective bulk crystals to structurally distorted monolayers, are important for the targeted optimization of GST material properties in memory devices, optical elements, and emerging nanoscale phase-change applications.

## Full-text entities

- **Chemicals:** GST (-), Te (MESH:D013691), Ge (MESH:D005857), Sb (MESH:D000965)

## Figures

12 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12986389/full.md

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Source: https://tomesphere.com/paper/PMC12986389