Catalyst-free synthesis of sub-5 nm silicon nanowire arrays with massive lattice contraction and wide bandgap

Authors
Gao, SenHong, SanghyunPark, SoohyungJung, Hyun YoungLiang, WentaoLee, YongheeAhn, Chi WonByun, Ji YoungSeo, JuyeonHahm, Myung GwanKim, HyeheeKim, KiwoongYi, YeonjinWang, HailongUpmanyu, MoneeshLee, Sung-GooHomma, YoshikazuTerrones, HumbertoJung, Yung Joon
Issue Date
2022-06
Publisher
Nature Publishing Group
Citation
Nature Communications, v.13, no.1
Abstract
The need for miniaturized and high-performance devices has attracted enormous attention to the development of quantum silicon nanowires. However, the preparation of abundant quantities of silicon nanowires with the effective quantum-confined dimension remains challenging. Here, we prepare highly dense and vertically aligned sub-5 nm silicon nanowires with length/diameter aspect ratios greater than 10,000 by developing a catalyst-free chemical vapor etching process. We observe an unusual lattice reduction of up to 20% within ultra-narrow silicon nanowires and good oxidation stability in air compared to conventional silicon. Moreover, the material exhibits a direct optical bandgap of 4.16 eV and quasi-particle bandgap of 4.75 eV with the large exciton binding energy of 0.59 eV, indicating the significant phonon and electronic confinement. The results may provide an opportunity to investigate the chemistry and physics of highly confined silicon quantum nanostructures and may explore their potential uses in nanoelectronics, optoelectronics, and energy systems. The preparation of quantum silicon nanowires, materials with potential application in high-performance nanodevices, is challenging. Here, the authors synthesize vertically aligned sub-5 nm silicon nanowires via a vapor phase silicon etching process; the resulting material features unusual lattice reduction and significant phonon and electronic confinement effects.
Keywords
SELF-LIMITING OXIDATION; ELASTIC PROPERTIES; OXIDE-GROWTH; SI NANOWIRES; LEDGE-FLOW; DIAMETER; SURFACE; SCATTERING; FABRICATION; ABSORPTION
ISSN
2041-1723
URI
https://pubs.kist.re.kr/handle/201004/115111
DOI
10.1038/s41467-022-31174-x
Appears in Collections:
KIST Article > 2022
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