Formation of hexagonal boron nitride by metal atomic vacancy-assisted b-n molecular diffusion

Seongjun Park; Jinyeong Lee; Han Sol Kim; Jong Bong Park; Kang Hyuck Lee; Sang A. Han; Sungwoo Hwang; Sang Woo Kim; Hyeon Jin Shin

doi:10.1021/nn505960b

Formation of hexagonal boron nitride by metal atomic vacancy-assisted b-n molecular diffusion

Seongjun Park, Jinyeong Lee, Han Sol Kim, Jong Bong Park, Kang Hyuck Lee, Sang A. Han, Sungwoo Hwang, Sang Woo Kim, Hyeon Jin Shin

Department of Materials Science and Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

Because of the low solubility of N atoms in metals, hexagonal boron nitride (h-BN) growth has explained by surface reaction on metal rather than by penetration/precipitation of B and N atoms in metal. Here, we present an impressive pathway of h-BN formation at the interface between Ni and oxide substrate based on B-N molecular diffusion into Ni through individual atomic vacancies. First-principles calculations confirmed the formation energies of the h-BN layers on and under the metal and the probability of B-N molecular diffusion in metal. The interface growth behavior depends on the species of metal catalysts, and these simulation results well support experimental results.

Original language	English
Pages (from-to)	633-638
Number of pages	6
Journal	ACS Nano
Volume	9
Issue number	1
DOIs	https://doi.org/10.1021/nn505960b
Publication status	Published - 2015 Jan 27

Bibliographical note

Publisher Copyright:
© 2014 American Chemical Society.

All Science Journal Classification (ASJC) codes

Materials Science(all)
Engineering(all)
Physics and Astronomy(all)

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10.1021/nn505960b

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title = "Formation of hexagonal boron nitride by metal atomic vacancy-assisted b-n molecular diffusion",

abstract = "Because of the low solubility of N atoms in metals, hexagonal boron nitride (h-BN) growth has explained by surface reaction on metal rather than by penetration/precipitation of B and N atoms in metal. Here, we present an impressive pathway of h-BN formation at the interface between Ni and oxide substrate based on B-N molecular diffusion into Ni through individual atomic vacancies. First-principles calculations confirmed the formation energies of the h-BN layers on and under the metal and the probability of B-N molecular diffusion in metal. The interface growth behavior depends on the species of metal catalysts, and these simulation results well support experimental results.",

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doi = "10.1021/nn505960b",

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T1 - Formation of hexagonal boron nitride by metal atomic vacancy-assisted b-n molecular diffusion

AU - Park, Seongjun

AU - Lee, Jinyeong

AU - Kim, Han Sol

AU - Park, Jong Bong

AU - Lee, Kang Hyuck

AU - Han, Sang A.

AU - Hwang, Sungwoo

AU - Kim, Sang Woo

AU - Shin, Hyeon Jin

PY - 2015/1/27

Y1 - 2015/1/27

N2 - Because of the low solubility of N atoms in metals, hexagonal boron nitride (h-BN) growth has explained by surface reaction on metal rather than by penetration/precipitation of B and N atoms in metal. Here, we present an impressive pathway of h-BN formation at the interface between Ni and oxide substrate based on B-N molecular diffusion into Ni through individual atomic vacancies. First-principles calculations confirmed the formation energies of the h-BN layers on and under the metal and the probability of B-N molecular diffusion in metal. The interface growth behavior depends on the species of metal catalysts, and these simulation results well support experimental results.

AB - Because of the low solubility of N atoms in metals, hexagonal boron nitride (h-BN) growth has explained by surface reaction on metal rather than by penetration/precipitation of B and N atoms in metal. Here, we present an impressive pathway of h-BN formation at the interface between Ni and oxide substrate based on B-N molecular diffusion into Ni through individual atomic vacancies. First-principles calculations confirmed the formation energies of the h-BN layers on and under the metal and the probability of B-N molecular diffusion in metal. The interface growth behavior depends on the species of metal catalysts, and these simulation results well support experimental results.

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Formation of hexagonal boron nitride by metal atomic vacancy-assisted b-n molecular diffusion

Abstract

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