# Strain and Band-Gap Engineering in Ge-Sn Alloys via P Doping

**Authors:** Slawomir Prucnal, Yonder Berenc\'en, Mao Wang, J\"org Grenzer,, Matthias Voelskow, Rene H\"ubner, Yuji Yamamoto, Alexander Scheit, Florian, B\"arwolf, Vitaly Zviagin, R\"udiger Schmidt-Grund, Marius Grundmann, Jerzy, \.Zuk, Marcin Turek, Andrzej Dro\'zdziel, Krzysztof Pyszniak, Robert, Kudrawiec, Maciej P. Polak, Lars Rebohle, Wolfgang Skorupa, Manfred Helm, and, Shengqiang Zhou

arXiv: 1901.01721 · 2019-01-08

## TL;DR

This study combines strain, alloying with Sn, and ultrahigh n-type doping to engineer the band gap of Ge-Sn alloys, demonstrating CMOS-compatible methods to achieve near-infrared optoelectronic applications.

## Contribution

It introduces a combined approach of strain, alloying, and doping to fabricate direct-band-gap Ge-Sn alloys using CMOS-compatible processes.

## Key findings

- Heavily P-doped Ge-Sn exhibits strain confirmed by x-ray diffraction and Raman spectroscopy.
- Band gap changes with P concentration are predicted by DFT and verified experimentally.
- Band-gap renormalization is partially offset by the Burstein-Moss effect at high electron concentrations.

## Abstract

Ge with a quasi-direct band gap can be realized by strain engineering, alloying with Sn, or ultrahigh n-type doping. In this work, we use all three approaches together to fabricate direct-band-gap Ge-Sn alloys. The heavily doped n-type Ge-Sn is realized with CMOS-compatible nonequilibrium material processing. P is used to form highly doped n-type Ge-Sn layers and to modify the lattice parameter of P-doped Ge-Sn alloys. The strain engineering in heavily-P-doped Ge-Sn films is confirmed by x-ray diffraction and micro Raman spectroscopy. The change of the band gap in P-doped Ge-Sn alloy as a function of P concentration is theoretically predicted by density functional theory and experimentally verified by near-infrared spectroscopic ellipsometry. According to the shift of the absorption edge, it is shown that for an electron concentration greater than 1x10^20 cm-3 the band-gap renormalization is partially compensated by the Burstein-Moss effect. These results indicate that Ge-based materials have high potential for use in near-infrared optoelectronic devices, fully compatible with CMOS technology.

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Source: https://tomesphere.com/paper/1901.01721