A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD

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A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD. / Mishin, Maxim V.; Zamotin, Kirill Y.; Protopopova, Vera S.; Uvarov, Andrey A.; Filatov, Leonid A.; Baryshnikova, Marina V.; Boricheva, Irina K.; Alexandrov, Sergey E.

In: PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS, Vol. 12, No. 7, 01.07.2015, p. 891-903.

Research output: Contribution to journalArticleScientificpeer-review

Harvard

Mishin, MV, Zamotin, KY, Protopopova, VS, Uvarov, AA, Filatov, LA, Baryshnikova, MV, Boricheva, IK & Alexandrov, SE 2015, 'A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD' PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS, vol. 12, no. 7, pp. 891-903. https://doi.org/10.1002/pssc.201510044

APA

Mishin, M. V., Zamotin, K. Y., Protopopova, V. S., Uvarov, A. A., Filatov, L. A., Baryshnikova, M. V., ... Alexandrov, S. E. (2015). A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD. PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS, 12(7), 891-903. https://doi.org/10.1002/pssc.201510044

Vancouver

Author

Mishin, Maxim V. ; Zamotin, Kirill Y. ; Protopopova, Vera S. ; Uvarov, Andrey A. ; Filatov, Leonid A. ; Baryshnikova, Marina V. ; Boricheva, Irina K. ; Alexandrov, Sergey E. / A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD. In: PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS. 2015 ; Vol. 12, No. 7. pp. 891-903.

Bibtex - Download

@article{32c31a62ac2b4e988acb8aa5f01dca48,
title = "A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD",
abstract = "The article covers the computational framework providing an insight on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD in an RF capacitive discharge. The proposed model is based on the solution of motion equations for neutral and charged nanoparticles in the plasma downstream area featuring a nonuniform distribution of electric potential. Within the model particles collisions are accounted by an O'Rourke derived stochastic method, reduction of computational time is attained by division of the nanoparticle stack into parcels. We argue that nanoparticles are mainly synthesized in the plasma downstream area. Size distribution of the particles is governed by their uneven motion in the nonuniform electric field. We demonstrate that particles of tens of nanometer in diameter result from coagulation of neutral nanoparticles, whereas the larger nanoparticles result from coagulation of charged particles. The model shows that charged particles trapped in the potential well in the vicinity of the discharge electrode grow up to micron size. The proposed model is validated by the experimental results of silicon dioxide nanoparticles synthesis; it may be extended to a vast range of materials provided certain modifications of the particles motion equations are done.",
keywords = "Atmospheric pressure PECVD, Inhomogeneous electrical field, Nano- and microparticle, Neutral and charged particle motion, Particle coagulation in vapour phase",
author = "Mishin, {Maxim V.} and Zamotin, {Kirill Y.} and Protopopova, {Vera S.} and Uvarov, {Andrey A.} and Filatov, {Leonid A.} and Baryshnikova, {Marina V.} and Boricheva, {Irina K.} and Alexandrov, {Sergey E.}",
year = "2015",
month = "7",
day = "1",
doi = "10.1002/pssc.201510044",
language = "English",
volume = "12",
pages = "891--903",
journal = "PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS",
issn = "1862-6351",
publisher = "Wiley-VCH Verlag",
number = "7",

}

RIS - Download

TY - JOUR

T1 - A computational view on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD

AU - Mishin, Maxim V.

AU - Zamotin, Kirill Y.

AU - Protopopova, Vera S.

AU - Uvarov, Andrey A.

AU - Filatov, Leonid A.

AU - Baryshnikova, Marina V.

AU - Boricheva, Irina K.

AU - Alexandrov, Sergey E.

PY - 2015/7/1

Y1 - 2015/7/1

N2 - The article covers the computational framework providing an insight on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD in an RF capacitive discharge. The proposed model is based on the solution of motion equations for neutral and charged nanoparticles in the plasma downstream area featuring a nonuniform distribution of electric potential. Within the model particles collisions are accounted by an O'Rourke derived stochastic method, reduction of computational time is attained by division of the nanoparticle stack into parcels. We argue that nanoparticles are mainly synthesized in the plasma downstream area. Size distribution of the particles is governed by their uneven motion in the nonuniform electric field. We demonstrate that particles of tens of nanometer in diameter result from coagulation of neutral nanoparticles, whereas the larger nanoparticles result from coagulation of charged particles. The model shows that charged particles trapped in the potential well in the vicinity of the discharge electrode grow up to micron size. The proposed model is validated by the experimental results of silicon dioxide nanoparticles synthesis; it may be extended to a vast range of materials provided certain modifications of the particles motion equations are done.

AB - The article covers the computational framework providing an insight on vapour phase coagulation of nanoparticles synthesized by atmospheric pressure PECVD in an RF capacitive discharge. The proposed model is based on the solution of motion equations for neutral and charged nanoparticles in the plasma downstream area featuring a nonuniform distribution of electric potential. Within the model particles collisions are accounted by an O'Rourke derived stochastic method, reduction of computational time is attained by division of the nanoparticle stack into parcels. We argue that nanoparticles are mainly synthesized in the plasma downstream area. Size distribution of the particles is governed by their uneven motion in the nonuniform electric field. We demonstrate that particles of tens of nanometer in diameter result from coagulation of neutral nanoparticles, whereas the larger nanoparticles result from coagulation of charged particles. The model shows that charged particles trapped in the potential well in the vicinity of the discharge electrode grow up to micron size. The proposed model is validated by the experimental results of silicon dioxide nanoparticles synthesis; it may be extended to a vast range of materials provided certain modifications of the particles motion equations are done.

KW - Atmospheric pressure PECVD

KW - Inhomogeneous electrical field

KW - Nano- and microparticle

KW - Neutral and charged particle motion

KW - Particle coagulation in vapour phase

UR - http://www.scopus.com/inward/record.url?scp=84935732151&partnerID=8YFLogxK

U2 - 10.1002/pssc.201510044

DO - 10.1002/pssc.201510044

M3 - Article

VL - 12

SP - 891

EP - 903

JO - PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS

JF - PHYSICA STATUS SOLIDI C: CURRENT TOPICS IN SOLID STATE PHYSICS

SN - 1862-6351

IS - 7

ER -

ID: 9186344