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Monolithic Metal–Semiconductor–Metal Heterostructures Enabling Next-Generation Germanium Nanodevices

Lukas Wind, Masiar Sistani, Zehao Song, Xavier Maeder, Darius Pohl, Johann Michler, Bernd Rellinghaus, W. Weber, Alois Lugstein

2021ACS Applied Materials & Interfaces21 citationsDOIOpen Access PDF

Abstract

Low-dimensional Ge is perceived as a promising building block for emerging optoelectronic devices. Here, we present a wafer-scale platform technology enabling monolithic Al-Ge-Al nanostructures fabricated by a thermally induced Al-Ge exchange reaction. Transmission electron microscopy confirmed the purity and crystallinity of the formed Al segments with an abrupt interface to the remaining Ge segment. In good agreement with the theoretical value of bulk Al-Ge Schottky junctions, a barrier height of 200 ± 20 meV was determined. Photoluminescence and μ-Raman measurements proved the optical quality of the Ge channel embedded in the monolithic Al-Ge-Al heterostructure. Together with the wafer-scale accessibility, the proposed fabrication scheme may give rise to the development of key components of a broad spectrum of emerging Ge-based devices requiring monolithic metal-semiconductor-metal heterostructures with high-quality interfaces.

Topics & Concepts

Materials scienceHeterojunctionOptoelectronicsGermaniumWaferSemiconductorFabricationSchottky barrierSchottky diodeNanotechnologyPhotoluminescenceRaman spectroscopySiliconOpticsDiodePathologyPhysicsMedicineAlternative medicineNanowire Synthesis and ApplicationsSemiconductor materials and devicesSemiconductor materials and interfaces
Monolithic Metal–Semiconductor–Metal Heterostructures Enabling Next-Generation Germanium Nanodevices | Litcius