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Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy. / Sabelfeld, K. K.; Kablukova, E. G.

In: Computational Materials Science, Vol. 141, 01.01.2018, p. 341-352.

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Harvard

Sabelfeld, KK & Kablukova, EG 2018, 'Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy', Computational Materials Science, vol. 141, pp. 341-352. https://doi.org/10.1016/j.commatsci.2017.09.046

APA

Sabelfeld, K. K., & Kablukova, E. G. (2018). Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy. Computational Materials Science, 141, 341-352. https://doi.org/10.1016/j.commatsci.2017.09.046

Vancouver

Sabelfeld KK, Kablukova EG. Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy. Computational Materials Science. 2018 Jan 1;141:341-352. doi: 10.1016/j.commatsci.2017.09.046

Author

Sabelfeld, K. K. ; Kablukova, E. G. / Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy. In: Computational Materials Science. 2018 ; Vol. 141. pp. 341-352.

BibTeX

@article{0e5351704a2a4b92b0be4c8b6c3d19c9,
title = "Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy",
abstract = "The stochastic model of the growth of an ensemble of GaN nanowires (NW) in a plasma-assisted molecular beam epitaxy suggested in our recent paper (Sabelfeld and Kablukova, 2016) is here further developed to include coalescence caused by bundling of nanowires. Moreover, in the extended model the Ga and N atoms are simulated separately to mimic nucleation of stable GaN islands which then start to grow in one direction with a fixed diameter. The bundling phenomenon is driven by the gain of surface energy at the expense of the elastic energy of bending and becomes energetically favorable once the nanowires exceed a certain critical length as found and described in our paper (Kaganer et al., 2016). The simulation model is based on a probabilistic description of surface diffusion, and takes into account the shading, multiple rescattering of atoms, and their survival probability. The model is implemented in a form of a direct simulation Monte Carlo algorithm. We present a comprehensive analysis of the kinetics of NW growth from an initial height distribution around tens of nanometers to NW heights up to several thousands nanometers which corresponds to the growth time in physical growth experiments about of 3–4 h. We compare the simulation results with our recently developed model without bundling and experimental results as well which show a good agreement. The series of simulations have basically confirmed the remarkable time evolution of the nanowire height distribution, namely, that under some conditions, now described more precisely, the NW height distribution is self-preserving and may become even narrower independent of the form of the initial NW height distribution. This phenomenon is explained by the multiple rescattering of atoms between the NW surfaces.",
keywords = "Adatoms, Bundling, Coalescence, Multiple scattering, Nanowires, Self-preserving distribution, Surface diffusion, MECHANISMS, NUCLEATION",
author = "Sabelfeld, {K. K.} and Kablukova, {E. G.}",
year = "2018",
month = jan,
day = "1",
doi = "10.1016/j.commatsci.2017.09.046",
language = "English",
volume = "141",
pages = "341--352",
journal = "Computational Materials Science",
issn = "0927-0256",
publisher = "Elsevier",

}

RIS

TY - JOUR

T1 - Stochastic model and simulation of growth and coalescence of spontaneously formed GaN nanowires in molecular beam epitaxy

AU - Sabelfeld, K. K.

AU - Kablukova, E. G.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - The stochastic model of the growth of an ensemble of GaN nanowires (NW) in a plasma-assisted molecular beam epitaxy suggested in our recent paper (Sabelfeld and Kablukova, 2016) is here further developed to include coalescence caused by bundling of nanowires. Moreover, in the extended model the Ga and N atoms are simulated separately to mimic nucleation of stable GaN islands which then start to grow in one direction with a fixed diameter. The bundling phenomenon is driven by the gain of surface energy at the expense of the elastic energy of bending and becomes energetically favorable once the nanowires exceed a certain critical length as found and described in our paper (Kaganer et al., 2016). The simulation model is based on a probabilistic description of surface diffusion, and takes into account the shading, multiple rescattering of atoms, and their survival probability. The model is implemented in a form of a direct simulation Monte Carlo algorithm. We present a comprehensive analysis of the kinetics of NW growth from an initial height distribution around tens of nanometers to NW heights up to several thousands nanometers which corresponds to the growth time in physical growth experiments about of 3–4 h. We compare the simulation results with our recently developed model without bundling and experimental results as well which show a good agreement. The series of simulations have basically confirmed the remarkable time evolution of the nanowire height distribution, namely, that under some conditions, now described more precisely, the NW height distribution is self-preserving and may become even narrower independent of the form of the initial NW height distribution. This phenomenon is explained by the multiple rescattering of atoms between the NW surfaces.

AB - The stochastic model of the growth of an ensemble of GaN nanowires (NW) in a plasma-assisted molecular beam epitaxy suggested in our recent paper (Sabelfeld and Kablukova, 2016) is here further developed to include coalescence caused by bundling of nanowires. Moreover, in the extended model the Ga and N atoms are simulated separately to mimic nucleation of stable GaN islands which then start to grow in one direction with a fixed diameter. The bundling phenomenon is driven by the gain of surface energy at the expense of the elastic energy of bending and becomes energetically favorable once the nanowires exceed a certain critical length as found and described in our paper (Kaganer et al., 2016). The simulation model is based on a probabilistic description of surface diffusion, and takes into account the shading, multiple rescattering of atoms, and their survival probability. The model is implemented in a form of a direct simulation Monte Carlo algorithm. We present a comprehensive analysis of the kinetics of NW growth from an initial height distribution around tens of nanometers to NW heights up to several thousands nanometers which corresponds to the growth time in physical growth experiments about of 3–4 h. We compare the simulation results with our recently developed model without bundling and experimental results as well which show a good agreement. The series of simulations have basically confirmed the remarkable time evolution of the nanowire height distribution, namely, that under some conditions, now described more precisely, the NW height distribution is self-preserving and may become even narrower independent of the form of the initial NW height distribution. This phenomenon is explained by the multiple rescattering of atoms between the NW surfaces.

KW - Adatoms

KW - Bundling

KW - Coalescence

KW - Multiple scattering

KW - Nanowires

KW - Self-preserving distribution

KW - Surface diffusion

KW - MECHANISMS

KW - NUCLEATION

UR - http://www.scopus.com/inward/record.url?scp=85030697314&partnerID=8YFLogxK

U2 - 10.1016/j.commatsci.2017.09.046

DO - 10.1016/j.commatsci.2017.09.046

M3 - Article

AN - SCOPUS:85030697314

VL - 141

SP - 341

EP - 352

JO - Computational Materials Science

JF - Computational Materials Science

SN - 0927-0256

ER -

ID: 12100742