AI Article Synopsis
- Silicon has traditionally been used in a cubic diamond lattice structure, making it an indirect-bandgap semiconductor that struggles with efficient light emission.
- Recent experiments have successfully demonstrated effective light emission from hexagonal germanium (Ge) and silicon-germanium (SiGe) alloys, achieving a radiative recombination lifetime of less than a nanosecond.
- The ability to tune the emission wavelength of hexagonal SiGe alloys while maintaining a direct bandgap suggests great potential for integrating electronic and optoelectronic functions in advanced devices.
Article Abstract
Silicon crystallized in the usual cubic (diamond) lattice structure has dominated the electronics industry for more than half a century. However, cubic silicon (Si), germanium (Ge) and SiGe alloys are all indirect-bandgap semiconductors that cannot emit light efficiently. The goal of achieving efficient light emission from group-IV materials in silicon technology has been elusive for decades. Here we demonstrate efficient light emission from direct-bandgap hexagonal Ge and SiGe alloys. We measure a sub-nanosecond, temperature-insensitive radiative recombination lifetime and observe an emission yield similar to that of direct-bandgap group-III-V semiconductors. Moreover, we demonstrate that, by controlling the composition of the hexagonal SiGe alloy, the emission wavelength can be continuously tuned over a broad range, while preserving the direct bandgap. Our experimental findings are in excellent quantitative agreement with ab initio theory. Hexagonal SiGe embodies an ideal material system in which to combine electronic and optoelectronic functionalities on a single chip, opening the way towards integrated device concepts and information-processing technologies.
Download full-text PDF |
Source |
|---|---|
| http://dx.doi.org/10.1038/s41586-020-2150-y | DOI Listing |
Publication Analysis
Top Keywords
Similar Publications
Direct bandgap quantum wells in hexagonal Silicon Germanium.
Nat Commun
June 2024
Department of Applied Physics, Eindhoven University of Technology, 5600 MB, Eindhoven, The Netherlands.
Silicon is indisputably the most advanced material for scalable electronics, but it is a poor choice as a light source for photonic applications, due to its indirect band gap. The recently developed hexagonal SiGe semiconductor features a direct bandgap at least for x > 0.65, and the realization of quantum heterostructures would unlock new opportunities for advanced optoelectronic devices based on the SiGe system.
View Article and Find Full Text PDFLow Surface Recombination in Hexagonal SiGe Alloy Nanowires: Implications for SiGe-Based Nanolasers.
ACS Appl Nano Mater
January 2024
Eindhoven University of Technology, Postbus 513, 5600 MB Eindhoven, The Netherlands.
Monolithic integration of silicon-based electronics and photonics could open the door toward many opportunities including on-chip optical data communication and large-scale application of light-based sensing devices in healthcare and automotive; by some, it is considered the Holy Grail of silicon photonics. The monolithic integration is, however, severely hampered by the inability of Si to efficiently emit light. Recently, important progress has been made by the demonstration of efficient light emission from direct-bandgap hexagonal SiGe (hex-SiGe) alloy nanowires.
View Article and Find Full Text PDFHexagonal-Ge Nanostructures with Direct-Bandgap Emissions in a Si-Based Light-Emitting Metasurface.
ACS Nano
January 2024
State Key Laboratory of Surface Physics and Department of Physics, Fudan University, Shanghai 200438, P. R. China.
Si-based emitters have been of great interest as an ideal light source for monolithic optical-electronic integrated circuits (MOEICs) on Si substrates. However, the general Si-based material is a diamond structure of cubic lattice with an indirect band gap, which cannot emit light efficiently. Here, hexagonal-Ge (H-Ge) nanostructures within a light-emitting metasurface consisting of a cubic-SiGe nanodisk array are reported.
View Article and Find Full Text PDFA family of robust Dirac cone materials: two-dimensional hexagonal MX (M = Zn/Cd/Hg, X = Si/Ge).
Phys Chem Chem Phys
April 2023
Faculty of Materials Science and Engineering, Kunming University of Science and Technology, Kunming, 650093, People's Republic of China.
The fascinating Dirac cone, which has produced some excellent properties in graphene, such as ballistic charge transport, ultra-high carrier mobility and the quantum Hall effect, has motivated researchers to design and study more two dimensional (2D) Dirac materials. In this work, we have designed a family of 2D Dirac cone materials MX (M = Zn/Cd/Hg, X = Si/Ge) and studied their superior properties by first principles calculation. The calculated cohesive energy, phonon dispersion and molecular dynamics confirmed the energetic, dynamic and thermodynamic stability of ZnGe, CdGe, HgSi, and CdSi monolayers.
View Article and Find Full Text PDFHexagonal silicon-germanium nanowire branches with tunable composition.
Nanotechnology
October 2022
Université Paris-Saclay, CNRS, Centre de Nanosciences et de Nanotechnologies, F-91120, Palaiseau, France.
Hexagonal SiGe-2H has been recently shown to have a direct bandgap, and holds the promise to be compatible with silicon technology. Hexagonal Si and Ge have been grown on an epitaxial lattice matched template consisting of wurtzite GaP and GaAs, respectively. Here, we present the growth of hexagonal Si and SiGe nanowire branches grown from a wurtzite stem by the vapor-liquid-solid growth mode, which is substantiated bytransmission electron microscopy.
View Article and Find Full Text PDFWant AI Summaries of new PubMed Abstracts delivered to your In-box?
Enter search terms and have AI summaries delivered each week - change queries or unsubscribe any time!