Atomic carbon adsorption on Ni nanoclusters: A DFT study

Qiang Wang; Kok Hwa Lim; Shuo Wang Yang; Yanhui Yang; Yuan Chen

doi:10.1007/s00214-010-0736-4

Atomic carbon adsorption on Ni nanoclusters: A DFT study

Qiang Wang, Kok Hwa Lim, Shuo Wang Yang, Yanhui Yang, Yuan Chen

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

34 Scopus citations

Abstract

Atomic carbon is a key intermediate interacting with transition metal clusters during the growth of carbon nanotube (CNT). Present density functional calculations studied the initial carbon adsorption on four Ni nanoclusters (N₁₃, N₁₅, N₃₈, and N₅₅). Our results show that carbon atoms preferentially adsorb on high-coordination sites, and carbon adsorption energies are larger on smaller Ni clusters. Ni cluster reconstruction plays an important role in creating more stable subsurface adsorption sites. The migration of adsorbed carbon atom on the surface threefold hollow site into the underlying interstitial subsurface positions is thermodynamically and kinetically feasible. The results indicate that the investigation of CNT growth mechanism should include both surface and subsurface carbon atoms, coupled with surface reconstruction of Ni nanoclusters.

Original language	English
Pages (from-to)	17-24
Number of pages	8
Journal	Theoretical Chemistry Accounts
Volume	128
Issue number	1
DOIs	https://doi.org/10.1007/s00214-010-0736-4
State	Published - Jan 2011
Externally published	Yes

Keywords

Carbon adsorption
Carbon nanotube
Growth mechanism
Nanocluster
Ni

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10.1007/s00214-010-0736-4

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title = "Atomic carbon adsorption on Ni nanoclusters: A DFT study",

abstract = "Atomic carbon is a key intermediate interacting with transition metal clusters during the growth of carbon nanotube (CNT). Present density functional calculations studied the initial carbon adsorption on four Ni nanoclusters (N13, N15, N38, and N55). Our results show that carbon atoms preferentially adsorb on high-coordination sites, and carbon adsorption energies are larger on smaller Ni clusters. Ni cluster reconstruction plays an important role in creating more stable subsurface adsorption sites. The migration of adsorbed carbon atom on the surface threefold hollow site into the underlying interstitial subsurface positions is thermodynamically and kinetically feasible. The results indicate that the investigation of CNT growth mechanism should include both surface and subsurface carbon atoms, coupled with surface reconstruction of Ni nanoclusters.",

keywords = "Carbon adsorption, Carbon nanotube, Growth mechanism, Nanocluster, Ni",

author = "Qiang Wang and Lim, {Kok Hwa} and Yang, {Shuo Wang} and Yanhui Yang and Yuan Chen",

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doi = "10.1007/s00214-010-0736-4",

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TY - JOUR

T1 - Atomic carbon adsorption on Ni nanoclusters

T2 - A DFT study

AU - Wang, Qiang

AU - Lim, Kok Hwa

AU - Yang, Shuo Wang

AU - Yang, Yanhui

AU - Chen, Yuan

PY - 2011/1

Y1 - 2011/1

N2 - Atomic carbon is a key intermediate interacting with transition metal clusters during the growth of carbon nanotube (CNT). Present density functional calculations studied the initial carbon adsorption on four Ni nanoclusters (N13, N15, N38, and N55). Our results show that carbon atoms preferentially adsorb on high-coordination sites, and carbon adsorption energies are larger on smaller Ni clusters. Ni cluster reconstruction plays an important role in creating more stable subsurface adsorption sites. The migration of adsorbed carbon atom on the surface threefold hollow site into the underlying interstitial subsurface positions is thermodynamically and kinetically feasible. The results indicate that the investigation of CNT growth mechanism should include both surface and subsurface carbon atoms, coupled with surface reconstruction of Ni nanoclusters.

AB - Atomic carbon is a key intermediate interacting with transition metal clusters during the growth of carbon nanotube (CNT). Present density functional calculations studied the initial carbon adsorption on four Ni nanoclusters (N13, N15, N38, and N55). Our results show that carbon atoms preferentially adsorb on high-coordination sites, and carbon adsorption energies are larger on smaller Ni clusters. Ni cluster reconstruction plays an important role in creating more stable subsurface adsorption sites. The migration of adsorbed carbon atom on the surface threefold hollow site into the underlying interstitial subsurface positions is thermodynamically and kinetically feasible. The results indicate that the investigation of CNT growth mechanism should include both surface and subsurface carbon atoms, coupled with surface reconstruction of Ni nanoclusters.

KW - Carbon adsorption

KW - Carbon nanotube

KW - Growth mechanism

KW - Nanocluster

KW - Ni

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DO - 10.1007/s00214-010-0736-4

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SN - 1432-881X

VL - 128

SP - 17

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JO - Theoretical Chemistry Accounts

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Atomic carbon adsorption on Ni nanoclusters: A DFT study

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