2016
DOI: 10.1002/jcc.24287
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Possible mechanism of BN fullerene formation from a boron cluster: Density‐functional tight‐binding molecular dynamics simulations

Abstract: We simulate the formation of a BN fullerene from an amorphous B cluster at 2000 K by quantum mechanical molecular dynamics based on the density-functional tight-binding method. We run 30 trajectories 200 ps in length, where N atoms are supplied around the target cluster, which is initially an amorphous B36 cluster. Most of the incident N atoms are promptly incorporated into the target cluster to form B-N-B bridges or NB3 pyramidal local substructures. BN fullerene formation is initiated by alternating BN ring … Show more

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Cited by 12 publications
(17 citation statements)
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“…The SCC-DFTB can also include reliable description of dispersions and weak interactions (Van der Waals and H-bonding) that are important roles for investigation of gas adsorption on a sensing material which is consistent with experimental observations [40,45,47,48]. Moreover, the SCC-DFTB was proved to be effective in the simulation studies of boron nitride nanostructures systems [49][50][51].…”
Section: Introductionsupporting
confidence: 72%
“…The SCC-DFTB can also include reliable description of dispersions and weak interactions (Van der Waals and H-bonding) that are important roles for investigation of gas adsorption on a sensing material which is consistent with experimental observations [40,45,47,48]. Moreover, the SCC-DFTB was proved to be effective in the simulation studies of boron nitride nanostructures systems [49][50][51].…”
Section: Introductionsupporting
confidence: 72%
“…The mechanism by which N atoms are incorporated into the B compounds to form alternant BN bond superstructures, which develops under high temperature conditions, has not been analyzed at all until recent theoretical work of Ohta [16], inspired by the experiments of Oku et al [17,18]. Ohta applied quantum-classical molecular dynamics (QCMDs), to successfully build BN nanocages bombarding a small boron cluster, B 36 , with nitrogen atoms each 4 ps, and treating the whole system as a canonical (NVT) ensemble at temperature of 2000 K. After 50 hits of N, the whole system self-organized into a nanocage, with dominant hexagon structure, using all boron atoms for BN bonds.…”
Section: Introductionmentioning
confidence: 99%
“…12. At typical temperature range (1500-2500 K) for producing BN nanocages 32,33 , isomer Ti & 4 with a heptagonal ring is the most abundant product, followed by Ti & 3. Despite being the lowest energy isomer at 0 K, Ti & 2 is only the third major product at synthesis temperatures up to~2400 K. Beyond that temperature, other relatively higher energy isomers (especially Ti & 7) become more competitive.…”
Section: Structural and Bonding Features Of Stable Ti(bn) 19 Isomersmentioning
confidence: 99%
“…Ti@(BN) n , ΔG c , defined by Eq. (1) in the text, at 1500, 2000, and 2500 K (indicated in blue, black, and red, respectively), the typical temperatures for producing BN nanocages 32,33 . Solid circles and empty diamonds represent, respectively, the exohedral and endohedral complexes.…”
Section: Structural and Bonding Features Of Stable Ti(bn) 19 Isomersmentioning
confidence: 99%
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