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Main Authors: Liu, Yinan, Briggs, Joseph P., Saiter, Sam, Singh, Meenakshi, Koh, Carolyn A., Taylor, P. Craig, Walker, Michael, Mateen, Khalid, Kane, Moussa, Collins, Reuben T.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.09755
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author Liu, Yinan
Briggs, Joseph P.
Saiter, Sam
Singh, Meenakshi
Koh, Carolyn A.
Taylor, P. Craig
Walker, Michael
Mateen, Khalid
Kane, Moussa
Collins, Reuben T.
author_facet Liu, Yinan
Briggs, Joseph P.
Saiter, Sam
Singh, Meenakshi
Koh, Carolyn A.
Taylor, P. Craig
Walker, Michael
Mateen, Khalid
Kane, Moussa
Collins, Reuben T.
contents While Si clathrates have been explored as promising direct bandgap semiconductors, their practical optoelectronic performance has been limited by high doping levels and structural defects. Hydrogen has long been used to improve the optoelectronic quality of conventional Si, yet its role in clathrate structures remains unexplored. In this study, we demonstrate that hydrogen (deuterium) can be incorporated into type II Si clathrate framework using remote plasma treatment. This process leads to the formation of NaD and SiD complexes, which significantly reduce both the Na donor density and dangling bond defects. Electron paramagnetic resonance confirms nearly a tenfold decrease in Na-related donor states, resulting in the lowest doping level reported in Si clathrates to date. Following passivation, the integrated photoluminescence intensity increases by a factor of 40, accompanied by a blue shift of the main emission peak, consistent with a transition closer to the intrinsic band edge. A new emission peak at 930 nm, attributed to hydrogen-related recombination centers, also appears. These improvements remain stable up to 400 oC. Altogether, this work establishes hydrogen passivation as a viable strategy for enhancing light emission in Si clathrates and opens a new pathway toward their application in Si-based light-emitting diodes and other direct-bandgap optoelectronic devices.
format Preprint
id arxiv_https___arxiv_org_abs_2511_09755
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle An optically enhanced crystalline silicon allotrope: hydrogen passivated type II silicon clathrate
Liu, Yinan
Briggs, Joseph P.
Saiter, Sam
Singh, Meenakshi
Koh, Carolyn A.
Taylor, P. Craig
Walker, Michael
Mateen, Khalid
Kane, Moussa
Collins, Reuben T.
Materials Science
While Si clathrates have been explored as promising direct bandgap semiconductors, their practical optoelectronic performance has been limited by high doping levels and structural defects. Hydrogen has long been used to improve the optoelectronic quality of conventional Si, yet its role in clathrate structures remains unexplored. In this study, we demonstrate that hydrogen (deuterium) can be incorporated into type II Si clathrate framework using remote plasma treatment. This process leads to the formation of NaD and SiD complexes, which significantly reduce both the Na donor density and dangling bond defects. Electron paramagnetic resonance confirms nearly a tenfold decrease in Na-related donor states, resulting in the lowest doping level reported in Si clathrates to date. Following passivation, the integrated photoluminescence intensity increases by a factor of 40, accompanied by a blue shift of the main emission peak, consistent with a transition closer to the intrinsic band edge. A new emission peak at 930 nm, attributed to hydrogen-related recombination centers, also appears. These improvements remain stable up to 400 oC. Altogether, this work establishes hydrogen passivation as a viable strategy for enhancing light emission in Si clathrates and opens a new pathway toward their application in Si-based light-emitting diodes and other direct-bandgap optoelectronic devices.
title An optically enhanced crystalline silicon allotrope: hydrogen passivated type II silicon clathrate
topic Materials Science
url https://arxiv.org/abs/2511.09755