APPLIED MACHINE LEARNING METHOD TO PREDICT CRACK PROPAGATION PATH IN POLYCRYSTALLINE GRAPHENE SHEET

被引：0

作者：

Elapolu, Mohan S. R. ^{[1
]}

Shishir, Md Imrul Reza ^{[1
]}

Tabarraei, Alireza ^{[1
]}

机构：

[1] Univ N Carolina, Dept Mech Engn & Engn Sci, 9201 Univ City Blvd, Charlotte, NC 28223 USA

来源：

PROCEEDINGS OF ASME 2021 INTERNATIONAL MECHANICAL ENGINEERING CONGRESS AND EXPOSITION (IMECE2021), VOL 12 | 2021年

基金：

美国国家科学基金会;

关键词：

Polycrystalline; Graphene; Machine Learning; Bidirectional Recurrent Neural Network; MECHANICAL-PROPERTIES; THERMAL-CONDUCTIVITY; ELECTRONIC-PROPERTIES; SUPERCAPACITOR; STRENGTH; NANOCOMPOSITES; ENERGY;

D O I：

暂无

中图分类号：

TH [机械、仪表工业];

学科分类号：

0802 ;

摘要：

A machine learning model is developed to predict the crack propagation path in polycrystalline graphene sheets. The dataset used for training the machine learning (ML) model is obtained from the molecular dynamics (MD) simulations. A training set of 700 samples has been used to train the ML model. Each training sample consists of an input image which contains the information of the initial configuration of precracked polycrystalline graphene sheet and an output image which contains the information of crack path. After training, the ML model can predict the crack propagation path in polycrystalline graphene sheet instantaneously, thus avoiding the computational costs involved with MD simulations.

引用

页数：9

共 85 条

[1] A review on mechanics and mechanical properties of 2D materials-Graphene and beyond
Akinwande, Deji
Brennan, Christopher J.
Bunch, J. Scott
Egberts, Philip
Felts, Jonathan R.
Gao, Huajian
Huang, Rui
Kim, Joon-Seok
Li, Teng
Li, Yao
Liechti, Kenneth M.
Lu, Nanshu
Park, Harold S.
Reed, Evan J.
Wang, Peng
Yakobson, Boris I.
Zhang, Teng
Zhang, Yong-Wei
Zhou, Yao
Zhu, Yong
[J]. EXTREME MECHANICS LETTERS, 2017, 13 : 42 - 77
[2] Mechanical property enhancement of one-dimensional nanostructures through defect-mediated strain engineering
Attariani, Hamed
Rezaei, S. Emad
Momeni, Kasra
[J]. EXTREME MECHANICS LETTERS, 2019, 27 : 66 - 75
[3] Superior thermal conductivity of single-layer graphene
Balandin, Alexander A.
Ghosh, Suchismita
Bao, Wenzhong
Calizo, Irene
Teweldebrhan, Desalegne
Miao, Feng
Lau, Chun Ning
[J]. NANO LETTERS, 2008, 8 (03) : 902 - 907
[4] Sensitive electromechanical sensors using viscoelastic graphene-polymer nanocomposites
Boland, Conor S.
Khan, Umar
Ryan, Gavin
Barwich, Sebastian
Charifou, Romina
Harvey, Andrew
Backes, Claudia
Li, Zheling
Ferreira, Mauro S.
Mobius, Matthias E.
Young, Robert J.
Coleman, Jonathan N.
[J]. SCIENCE, 2016, 354 (6317) : 1257 - 1260
[5] Ultrahigh electron mobility in suspended graphene
Bolotin, K. I.
Sikes, K. J.
Jiang, Z.
Klima, M.
Fudenberg, G.
Hone, J.
Kim, P.
Stormer, H. L.
[J]. SOLID STATE COMMUNICATIONS, 2008, 146 (9-10) : 351 - 355
[6] Electromechanical resonators from graphene sheets
Bunch, J. Scott
van der Zande, Arend M.
Verbridge, Scott S.
Frank, Ian W.
Tanenbaum, David M.
Parpia, Jeevak M.
Craighead, Harold G.
McEuen, Paul L.
[J]. SCIENCE, 2007, 315 (5811) : 490 - 493
[7] The electronic properties of graphene
Castro Neto, A. H.
Guinea, F.
Peres, N. M. R.
Novoselov, K. S.
Geim, A. K.
[J]. REVIEWS OF MODERN PHYSICS, 2009, 81 (01) : 109 - 162
[8] High capacity reversible hydrogen storage in titanium doped 2D carbon allotrope Ψ-graphene: Density Functional Theory investigations
Chakraborty, Brahamananda
Ray, Pranoy
Garg, Nandini
Banerjee, Srikumar
[J]. INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2021, 46 (05) : 4154 - 4167
[9] Chollet, KERAS
[10] Influence of temperature and free edges on the mechanical properties of graphene
Dewapriya, M. A. N.
Phani, A. Srikantha
Rajapakse, R. K. N. D.
[J]. MODELLING AND SIMULATION IN MATERIALS SCIENCE AND ENGINEERING, 2013, 21 (06)

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