Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition

Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition

Nanocomposite SiOx particles have been produced by a single step plasma spray physical vapor deposition (PS-PVD) through rapid condensation of SiO vapors and the subsequent disproportionation reaction. Core-shell nanoparticles, in which 15 nm crystalline Si is embedded within the amorphous SiOx matr...

Full description

Bibliographic Details
Main Authors: Tohru Tashiro, Masashi Dougakiuchi, Makoto Kambara
Format: Article
Language:English
Published: Taylor & Francis Group 2016-01-01
Series:Science and Technology of Advanced Materials
Subjects:
lithium ion batteries
silicon monoxide nanoparticle
disproportionation reaction
plasma spray
Online Access:http://dx.doi.org/10.1080/14686996.2016.1240574
id doaj-5c69262a6c6f474b894743dfb4f1a03e
record_format Article
spelling doaj-5c69262a6c6f474b894743dfb4f1a03e2021-07-06T11:30:14ZengTaylor & Francis GroupScience and Technology of Advanced Materials1468-69961878-55142016-01-0117174475210.1080/14686996.2016.12405741240574Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor depositionTohru Tashiro0Masashi Dougakiuchi1Makoto Kambara2Department of Materials Engineering, The University of TokyoShimane Institute for Industrial TechnologyDepartment of Materials Engineering, The University of TokyoNanocomposite SiOx particles have been produced by a single step plasma spray physical vapor deposition (PS-PVD) through rapid condensation of SiO vapors and the subsequent disproportionation reaction. Core-shell nanoparticles, in which 15 nm crystalline Si is embedded within the amorphous SiOx matrix, form under typical PS-PVD conditions, while 10 nm amorphous particles are formed when processed with an increased degree of non-equilibrium effect. Addition of CH4 promotes reduction in the oxygen content x of SiOx, and thereby increases the Si volume in a nanocomposite particle. As a result, core-shell nanoparticles with x = 0.46 as anode exhibit increased initial efficiency and the capacity of lithium ion batteries while maintaining cyclability. Furthermore, it is revealed that the disproportionation reaction of SiO is promoted in nanosized particles attaining increased Si diffusivity by two orders of magnitude compared to that in bulk, which facilitates instantaneous composite nanoparticle formation during PS-PVD.http://dx.doi.org/10.1080/14686996.2016.1240574lithium ion batteriessilicon monoxide nanoparticledisproportionation reactionplasma spray
collection DOAJ
language English
format Article
sources DOAJ
author Tohru Tashiro
Masashi Dougakiuchi
Makoto Kambara
spellingShingle Tohru Tashiro
Masashi Dougakiuchi
Makoto Kambara
Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
Science and Technology of Advanced Materials
lithium ion batteries
silicon monoxide nanoparticle
disproportionation reaction
plasma spray
author_facet Tohru Tashiro
Masashi Dougakiuchi
Makoto Kambara
author_sort Tohru Tashiro
title Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
title_short Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
title_full Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
title_fullStr Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
title_full_unstemmed Instantaneous formation of SiOx nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
title_sort instantaneous formation of siox nanocomposite for high capacity lithium ion batteries by enhanced disproportionation reaction during plasma spray physical vapor deposition
publisher Taylor & Francis Group
series Science and Technology of Advanced Materials
issn 1468-6996
1878-5514
publishDate 2016-01-01
description Nanocomposite SiOx particles have been produced by a single step plasma spray physical vapor deposition (PS-PVD) through rapid condensation of SiO vapors and the subsequent disproportionation reaction. Core-shell nanoparticles, in which 15 nm crystalline Si is embedded within the amorphous SiOx matrix, form under typical PS-PVD conditions, while 10 nm amorphous particles are formed when processed with an increased degree of non-equilibrium effect. Addition of CH4 promotes reduction in the oxygen content x of SiOx, and thereby increases the Si volume in a nanocomposite particle. As a result, core-shell nanoparticles with x = 0.46 as anode exhibit increased initial efficiency and the capacity of lithium ion batteries while maintaining cyclability. Furthermore, it is revealed that the disproportionation reaction of SiO is promoted in nanosized particles attaining increased Si diffusivity by two orders of magnitude compared to that in bulk, which facilitates instantaneous composite nanoparticle formation during PS-PVD.
topic lithium ion batteries
silicon monoxide nanoparticle
disproportionation reaction
plasma spray
url http://dx.doi.org/10.1080/14686996.2016.1240574
work_keys_str_mv AT tohrutashiro instantaneousformationofsioxnanocompositeforhighcapacitylithiumionbatteriesbyenhanceddisproportionationreactionduringplasmasprayphysicalvapordeposition
AT masashidougakiuchi instantaneousformationofsioxnanocompositeforhighcapacitylithiumionbatteriesbyenhanceddisproportionationreactionduringplasmasprayphysicalvapordeposition
AT makotokambara instantaneousformationofsioxnanocompositeforhighcapacitylithiumionbatteriesbyenhanceddisproportionationreactionduringplasmasprayphysicalvapordeposition
_version_ 1721317534233264128

Similar Items