Direct bandgap emission from strain-doped germanium
Mar 1, 2024·
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0 min read
Linding Yuan
Shu-Shen Li
Jun-Wei Luo
Abstract
Germanium (Ge) is an attractive material for Silicon (Si) compatible
optoelectronics, but the nature of its indirect bandgap renders it an
inefficient light emitter. Drawing inspiration from the significant
expansion of Ge volume upon lithiation as a Lithium (Li) ion battery
anode, here, we propose incorporating Li atoms into the Ge to cause
lattice expansion to achieve the desired tensile strain for a
transition from an indirect to a direct bandgap. Our first-principles
calculations show that a minimal amount of 3 at.% Li can convert Ge
from an indirect to a direct bandgap to possess a dipole transition
matrix element comparable to that of typical direct bandgap
semiconductors. To enhance compatibility with Si Complementary-Metal-Oxide-Semiconductors
(CMOS) technology, we additionally suggest implanting noble gas atoms
instead of Li atoms. We also demonstrate the tunability of the
direct-bandgap emission wavelength through the manipulation of dopant
concentration, enabling coverage of the mid-infrared to far-infrared
spectrum. This Ge-based light-emitting approach presents exciting
prospects for surpassing the physical limitations of Si technology in
the field of photonics and calls for experimental proof-of-concept
studies.
Type
Publication
Nature Communications 15, 2400 (2024)

Authors
I develop predictive theories of condensed matter materials and propose them for experimentalists to make. My work pairs first-principles calculations with symmetry analysis to discover new classes of materials with interesting electronic and magnetic properties. Specific material class of interests include semicondcutors and ferroic materials. My recent interest extends to integrating these methods into agentic workflows to accelerate materials discovery.
I moved to Evanston in May 2023 to join the Rondinelli Group at Northwestern University as a research associate.