Ge Epitaxy at Ultralow Growth Temperatures Enabled by a Pristine Growth Environment

Overview

Journal ACS Appl Electron Mater

Publisher American Chemical Society

Date 2024 Dec 30

PMID 39735569

Authors

Christoph Wilflingseder

Johannes Aberl

Enrique Prado Navarrete

Gunter Hesser

Heiko Groiss

Maciej O Liedke

Maik Butterling

Andreas Wagner

Eric Hirschmann

Cedric Corley-Wiciak

Marvin H Zoellner

Giovanni Capellini

Thomas Fromherz

Moritz Brehm

Affiliations

Soon will be listed here.

Abstract

Germanium (Ge), the next-in-line group-IV material, bears great potential to add functionality and performance to next-generation nanoelectronics and solid-state quantum transport based on silicon (Si) technology. Here, we investigate the direct epitaxial growth of two-dimensional high-quality crystalline Ge layers on Si deposited at ultralow growth temperatures ( = 100-350 °C) and pristine growth pressures (≲10 mbar). First, we show that a decreasing does not degrade the crystal quality of homoepitaxial Ge/Ge(001) by comparing the point defect density using positron annihilation lifetime spectroscopy. Subsequently, we present a systematic investigation of the Ge/Si(001) heteroepitaxy, varying the Ge coverage (Θ 1, 2, 4, 8, 12, and 16 nm) and (100-300 °C, in increments of 50 °C) to assess the influence of these parameters on the layer's structural quality. Atomic force microscopy revealed a rippled surface topography with superimposed grainy features and the absence of three-dimensional structures, such as quantum dots. Transmission electron microscopy unveiled pseudomorphic grains of highly crystalline growth separated by defective domains. Thanks to nanobeam scanning X-ray diffraction measurements, we were able to evidence the lattice strain fluctuations due to the ripple-like structure of the layers. We conclude that the heteroepitaxial strain contributes to the formation of the ripples, which originate from the kinetic limitations of the ultralow temperatures.

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