Oxidation Mechanism of Graphene Coating on an Aluminum Slab

Xiaoya Chang; Dongping Chen

doi:10.1007/978-981-19-1774-5_28

Oxidation Mechanism of Graphene Coating on an Aluminum Slab

Xiaoya Chang, Dongping Chen^*

^*Corresponding author for this work

School of Mechatronical Engineering

Beijing Institute of Technology

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Surface engineering is a promising approach to enhance the combustion performance of energetic materials. The carbon-based coating provides several advantages in ignition temperature, processability and compatibility. This work conducted the reactive molecular dynamic simulations on aluminium slabs with graphene coating to elaborate the underlying oxidation mechanisms. The combustion evolution of coated slabs is examined under the flow impact to capture the anisotropic nature in explosion. From the analysis of stress distributions and morphological evolutions, the deformation and disruption mechanisms of bilayer graphene are discussed in detail. Successive surface collisions result in the preferable crack on the lower graphene layer close to the aluminum substrate, rather than the upper layer. Compared with alumina coating, the modified slab exhibits an enhanced heat release due to the better mass diffusion. We further identify the bond populations and oxidation products to elaborate the reaction mechanism and highlight the intense impulse of modified slab. These numerical findings are expected to provide a theoretical guidance for the design of next-generation energetic materials.

Original language	English
Title of host publication	2021 International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials
Editors	Alon Gany, Xiaolong Fu
Publisher	Springer Science and Business Media Deutschland GmbH
Pages	353-363
Number of pages	11
ISBN (Print)	9789811917738
DOIs	https://doi.org/10.1007/978-981-19-1774-5_28
Publication status	Published - 2022
Event	2nd International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials, ICCN 2021 - Weihai, China Duration: 19 Aug 2021 → 20 Aug 2021

Publication series

Name	Springer Proceedings in Physics
Volume	276
ISSN (Print)	0930-8989
ISSN (Electronic)	1867-4941

Conference

Conference	2nd International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials, ICCN 2021
Country/Territory	China
City	Weihai
Period	19/08/21 → 20/08/21

Keywords

Aluminum
Graphene
Oxidation mechanism
ReaxFF
Surface coating

Access to Document

10.1007/978-981-19-1774-5_28

Cite this

Chang, X., & Chen, D. (2022). Oxidation Mechanism of Graphene Coating on an Aluminum Slab. In A. Gany, & X. Fu (Eds.), 2021 International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials (pp. 353-363). (Springer Proceedings in Physics; Vol. 276). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-981-19-1774-5_28

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title = "Oxidation Mechanism of Graphene Coating on an Aluminum Slab",

abstract = "Surface engineering is a promising approach to enhance the combustion performance of energetic materials. The carbon-based coating provides several advantages in ignition temperature, processability and compatibility. This work conducted the reactive molecular dynamic simulations on aluminium slabs with graphene coating to elaborate the underlying oxidation mechanisms. The combustion evolution of coated slabs is examined under the flow impact to capture the anisotropic nature in explosion. From the analysis of stress distributions and morphological evolutions, the deformation and disruption mechanisms of bilayer graphene are discussed in detail. Successive surface collisions result in the preferable crack on the lower graphene layer close to the aluminum substrate, rather than the upper layer. Compared with alumina coating, the modified slab exhibits an enhanced heat release due to the better mass diffusion. We further identify the bond populations and oxidation products to elaborate the reaction mechanism and highlight the intense impulse of modified slab. These numerical findings are expected to provide a theoretical guidance for the design of next-generation energetic materials.",

keywords = "Aluminum, Graphene, Oxidation mechanism, ReaxFF, Surface coating",

author = "Xiaoya Chang and Dongping Chen",

note = "Publisher Copyright: {\textcopyright} 2022, China Ordnance Society.; 2nd International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials, ICCN 2021 ; Conference date: 19-08-2021 Through 20-08-2021",

year = "2022",

doi = "10.1007/978-981-19-1774-5_28",

language = "English",

isbn = "9789811917738",

series = "Springer Proceedings in Physics",

publisher = "Springer Science and Business Media Deutschland GmbH",

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editor = "Alon Gany and Xiaolong Fu",

booktitle = "2021 International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials",

address = "Germany",

}

Chang, X & Chen, D 2022, Oxidation Mechanism of Graphene Coating on an Aluminum Slab. in A Gany & X Fu (eds), 2021 International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials. Springer Proceedings in Physics, vol. 276, Springer Science and Business Media Deutschland GmbH, pp. 353-363, 2nd International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials, ICCN 2021, Weihai, China, 19/08/21. https://doi.org/10.1007/978-981-19-1774-5_28

Oxidation Mechanism of Graphene Coating on an Aluminum Slab. / Chang, Xiaoya; Chen, Dongping.
2021 International Conference on Development and Application of Carbon Nanomaterials in Energetic Materials. ed. / Alon Gany; Xiaolong Fu. Springer Science and Business Media Deutschland GmbH, 2022. p. 353-363 (Springer Proceedings in Physics; Vol. 276).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Oxidation Mechanism of Graphene Coating on an Aluminum Slab

AU - Chang, Xiaoya

AU - Chen, Dongping

PY - 2022

Y1 - 2022

N2 - Surface engineering is a promising approach to enhance the combustion performance of energetic materials. The carbon-based coating provides several advantages in ignition temperature, processability and compatibility. This work conducted the reactive molecular dynamic simulations on aluminium slabs with graphene coating to elaborate the underlying oxidation mechanisms. The combustion evolution of coated slabs is examined under the flow impact to capture the anisotropic nature in explosion. From the analysis of stress distributions and morphological evolutions, the deformation and disruption mechanisms of bilayer graphene are discussed in detail. Successive surface collisions result in the preferable crack on the lower graphene layer close to the aluminum substrate, rather than the upper layer. Compared with alumina coating, the modified slab exhibits an enhanced heat release due to the better mass diffusion. We further identify the bond populations and oxidation products to elaborate the reaction mechanism and highlight the intense impulse of modified slab. These numerical findings are expected to provide a theoretical guidance for the design of next-generation energetic materials.

AB - Surface engineering is a promising approach to enhance the combustion performance of energetic materials. The carbon-based coating provides several advantages in ignition temperature, processability and compatibility. This work conducted the reactive molecular dynamic simulations on aluminium slabs with graphene coating to elaborate the underlying oxidation mechanisms. The combustion evolution of coated slabs is examined under the flow impact to capture the anisotropic nature in explosion. From the analysis of stress distributions and morphological evolutions, the deformation and disruption mechanisms of bilayer graphene are discussed in detail. Successive surface collisions result in the preferable crack on the lower graphene layer close to the aluminum substrate, rather than the upper layer. Compared with alumina coating, the modified slab exhibits an enhanced heat release due to the better mass diffusion. We further identify the bond populations and oxidation products to elaborate the reaction mechanism and highlight the intense impulse of modified slab. These numerical findings are expected to provide a theoretical guidance for the design of next-generation energetic materials.

KW - Aluminum

KW - Graphene

KW - Oxidation mechanism

KW - ReaxFF

KW - Surface coating

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Y2 - 19 August 2021 through 20 August 2021

ER -

Oxidation Mechanism of Graphene Coating on an Aluminum Slab

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