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Diamondene has received the attention of scientists recently because of its brilliant physical properties. But, owing to the limitations of current technology, defects are indispensable during the production of diamondene. In this work, the effect of boundary cracks on the tensile properties and damage mechanism of diamondene are investigated by using molecular dynamics method. The results show that the crack leads the tensile properties of diamondene to be weakened, and the elastic modulus, cracking strain, and cracking stress of diamondene containing a boundary crack to become less than those of diamondene without cracks. As for the failure mode, the damage of crack-free diamondene starts near the mobile end, while the damage of diamondene with a boundary crack starts at the crack tip. After the cracking strain has been reached, the crack will form a penetration rupture without further loading and the crack-free diamondene completely loses its load-bearing capacity. However, in diamondene with a boundary crack, the load still needs adding, and the crack will form a penetration crack after the cracking strain has been reached through several extensions. Furthermore, the tensile properties of diamondene with a boundary crackare strongly dependent on temperature, and decrease significantly when the temperature increases. Changes in the location, length and direction of cracks can cause the tensile properties and damage mechanism of the crack-containing diamondene to change.
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Keywords:
- diamondene /
- boundary cracks /
- mechanical characteristics /
- damage mechanism
[1] Novoselov K S, Geim A K, Morozov S V, Jiang D, Zhang Y, Dubonos S V, Grigorieva I V, Firsov A A 2004 Science 306 666
Google Scholar
[2] Miao T, Yeom S, Wang P, Standley B, Bockrath M 2014 Nano Lett. 14 2982
Google Scholar
[3] Zhao J, Zhang G Y, Shi D X 2013 Chin. Phys. B 22 057701
Google Scholar
[4] Xu L Q, Wei N, Zheng Y P 2012 J. Mater. Chem. 22 1435
Google Scholar
[5] Jiang J W, Leng J T, Li J X, Guo Z R, Chang T C, Guo X M, Zhang T Y 2017 Carbon 118 370
Google Scholar
[6] Cai K, Luo J, Ling Y R, Wan J, Qin Q H 2016 Sci. Rep. 6 35157
Google Scholar
[7] 吴玉程 2019 材料热处理学报 5 16
Wu Y C 2019 Trans. Mater. Heat Treat 5 16
[8] Barboza A P M, Guimaraes M H D, Massote D V P, Campos L C, Barbosa N N M, Cancado L G, Lacerda R G, Chacham H, Mazzoni M S C, Neves B R A 2011 Adv. Mater. 23 3014
Google Scholar
[9] Pakornchote T, Ektarawong A, Alling B, Pinsook U, Tancharakorn S, Busayaporn W, Bovornratanaraks T 2019 Carbon 146 468
Google Scholar
[10] Shi J, Cai K, Xie Y M 2018 Mater. Des. 156 125
Google Scholar
[11] Cai K, Wang L, Xie Y M 2018 Mater. Des. 149 34
Google Scholar
[12] Wang L, Cai K, Wei S Y, Xie Y M 2018 Phys. Chem. Chem. Phys. 20 21136
Google Scholar
[13] Wang L, Cai K, Xie Y M, Qin Q H 2019 Nanotechnology 30 075702
Google Scholar
[14] Wang L, Li D H, Shi J, Cai K 2020 Comput. Mater. Sci. 173 109459
Google Scholar
[15] Martins L G P, Matos M J S, Paschoal A R, Freire P T C, Andrade N F, A A L, Kong J, Neves B R A, de Oliveira A B, Mazzoni M S C, Filho A G S, Cançado L G 2017 Nat. Commun. 8 96
Google Scholar
[16] Gao Y, Cao T F, Cellini F, Berger C, de Heer W A, Tosatti E, Riedo E, Bongiorno A 2018 Nat. Nanotechnol. 13 133
Google Scholar
[17] 辛浩, 韩强, 姚小虎 2008 57 4391
Google Scholar
Xin H, Han Q, Yao X H 2008 Acta Phys. Sin. 57 4391
Google Scholar
[18] Wang M C, Yan C, Ma L, Hu N, Chen M W 2012 Comput. Mater. Sci. 54 236
Google Scholar
[19] Wang C H, Han Q, Xin D R 2015 Mol. Simul. 41 1
Google Scholar
[20] Fu Y, Ragab T, Basaran C T 2016 Comput. Mater. Sci. 124 142
Google Scholar
[21] An M R, Deng Q, Li Y L, Song H Y, Su M J 2018 Superlattices Microst. 123 172
Google Scholar
[22] 王磊, 张冉冉, 方炜 2019 68 064210
Google Scholar
Wang L, Zhang R R, Fang W 2019 Acta Phys. Sin. 68 064210
Google Scholar
[23] Li Y B, Sinitskii A, Tour J M 2008 Nat. Mater. 7 966
Google Scholar
[24] Stuart S J, Tutein A B, Harrison J A 2000 J. Chem. Phys. 112 6472
Google Scholar
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图 1 金刚石烯模型构型图 (a) 金刚石烯模型的左视图、俯视图和正视图; (b) 金刚石烯胞元的构型图
Figure 1. Conformation diagram of diamondene model: (a) Three views of diamondene model; (b) conformation diagram of the diamondene unit cell.
图 2 三种模型在10 K温度下的单轴拉伸曲线图 (a) 无裂缝金刚石烯, (b) 含边界裂缝金刚石烯和(c)双层石墨烯的拉伸过程应力-应变和VPEA-应变曲线; (d) 三者的起裂应变与起裂应力对比
Figure 2. Plots of the three models during stretching at 10 K: Stress-strain and VPEA-strain curves during stretching of pristine diamondene (a), diamondene with a boundary crack (b) and bilayer graphene with a boundary crack (c); (d) cracking strain versus cracking stress for the three.
图 3 无裂缝金刚石烯单轴拉伸过程构型图
Figure 3. Uniaxial stretching process configuration of pristine diamondene.
图 4 无裂缝金刚石烯拉伸过程中L12, L23和α123值的变化
Figure 4. Variation of L12, L23 and α123 values during stretching of pristine diamondene.
图 5 含边界裂缝金刚石烯单轴拉伸过程构型图
Figure 5. Uniaxial stretching process configuration of diamondene with a boundary crack.
图 6 含边界裂缝双层石墨烯单轴拉伸过程构型图
Figure 6. Uniaxial stretching process conformation of bilayer graphene with a boundary crack.
图 7 含边界裂缝金刚石烯(a)和双层石墨烯(b)的构型图对比
Figure 7. Comparison of conformation diagram of diamondene containing a boundary crack (a) and bilayer graphene containing a boundary crack (b).
图 8 不同温度下以0.001 nm位移增量进行含边界裂缝金刚石烯的单轴拉伸过程曲线图 (a) 应力-应变曲线; (b) 势能随弛豫时间变化曲线; (c) 起裂应变随温度变化曲线; (d) 起裂应力随温度变化曲线
Figure 8. Plots of uniaxial stretching processes with a boundary crack in diamondene at different temperatures in 0.001 nm displacement increases: (a) Stress-strain curve; (b) potential energy with relaxation time; (c) cracking strain with temperature; (d) cracking stress with temperature.
图 9 不同温度下含边界裂缝金刚石烯破坏构型图
Figure 9. Conformation diagram of the moment of damage of diamondene containing a boundary crack at different temperatures.
图 10 含边界裂缝金刚石烯与含中心裂缝金刚石烯应力-应变曲线
Figure 10. Stress-strain curves of diamondene with a boundary crack and diamondene with a central crack.
图 11 含中心裂缝金刚石烯构型图
Figure 11. Conformation diagram of diamondene containing a central crack.
图 12 不同裂缝长度下含边界裂缝金刚石烯的曲线图 (a) 应力-应变曲线; (b) 起裂应变-裂缝长度曲线
Figure 12. Curves of diamondene with a boundary crack for different crack lengths: (a) Stress-strain curves; (b) crack initiation strain-crack length curve.
图 13 不同裂缝长度下含边界裂缝金刚石烯破坏时刻构型图
Figure 13. Conformation diagram of the moment of damage of diamondene containing a boundary crack at different crack lengths.
图 14 不同裂缝方向的含边界裂缝金刚石烯初始构型图 (a) 30°; (b) 45°; (c) 60°
Figure 14. Conformation diagram of diamondene containing a boundary crack with different crack directions: (a) 30°; (b) 45°; (c) 60°.
图 15 不同裂缝方向下含边界裂缝金刚石烯的应力-应变曲线图
Figure 15. Stress-strain curves of diamondene with a boundary crack for different crack directions.
图 16 不同裂缝方向下含边界裂缝金刚石烯破坏时刻构型图
Figure 16. Conformation diagram of the moment of damage of diamondene containing a boundary crack at different crack directions.
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[1] Novoselov K S, Geim A K, Morozov S V, Jiang D, Zhang Y, Dubonos S V, Grigorieva I V, Firsov A A 2004 Science 306 666
Google Scholar
[2] Miao T, Yeom S, Wang P, Standley B, Bockrath M 2014 Nano Lett. 14 2982
Google Scholar
[3] Zhao J, Zhang G Y, Shi D X 2013 Chin. Phys. B 22 057701
Google Scholar
[4] Xu L Q, Wei N, Zheng Y P 2012 J. Mater. Chem. 22 1435
Google Scholar
[5] Jiang J W, Leng J T, Li J X, Guo Z R, Chang T C, Guo X M, Zhang T Y 2017 Carbon 118 370
Google Scholar
[6] Cai K, Luo J, Ling Y R, Wan J, Qin Q H 2016 Sci. Rep. 6 35157
Google Scholar
[7] 吴玉程 2019 材料热处理学报 5 16
Wu Y C 2019 Trans. Mater. Heat Treat 5 16
[8] Barboza A P M, Guimaraes M H D, Massote D V P, Campos L C, Barbosa N N M, Cancado L G, Lacerda R G, Chacham H, Mazzoni M S C, Neves B R A 2011 Adv. Mater. 23 3014
Google Scholar
[9] Pakornchote T, Ektarawong A, Alling B, Pinsook U, Tancharakorn S, Busayaporn W, Bovornratanaraks T 2019 Carbon 146 468
Google Scholar
[10] Shi J, Cai K, Xie Y M 2018 Mater. Des. 156 125
Google Scholar
[11] Cai K, Wang L, Xie Y M 2018 Mater. Des. 149 34
Google Scholar
[12] Wang L, Cai K, Wei S Y, Xie Y M 2018 Phys. Chem. Chem. Phys. 20 21136
Google Scholar
[13] Wang L, Cai K, Xie Y M, Qin Q H 2019 Nanotechnology 30 075702
Google Scholar
[14] Wang L, Li D H, Shi J, Cai K 2020 Comput. Mater. Sci. 173 109459
Google Scholar
[15] Martins L G P, Matos M J S, Paschoal A R, Freire P T C, Andrade N F, A A L, Kong J, Neves B R A, de Oliveira A B, Mazzoni M S C, Filho A G S, Cançado L G 2017 Nat. Commun. 8 96
Google Scholar
[16] Gao Y, Cao T F, Cellini F, Berger C, de Heer W A, Tosatti E, Riedo E, Bongiorno A 2018 Nat. Nanotechnol. 13 133
Google Scholar
[17] 辛浩, 韩强, 姚小虎 2008 57 4391
Google Scholar
Xin H, Han Q, Yao X H 2008 Acta Phys. Sin. 57 4391
Google Scholar
[18] Wang M C, Yan C, Ma L, Hu N, Chen M W 2012 Comput. Mater. Sci. 54 236
Google Scholar
[19] Wang C H, Han Q, Xin D R 2015 Mol. Simul. 41 1
Google Scholar
[20] Fu Y, Ragab T, Basaran C T 2016 Comput. Mater. Sci. 124 142
Google Scholar
[21] An M R, Deng Q, Li Y L, Song H Y, Su M J 2018 Superlattices Microst. 123 172
Google Scholar
[22] 王磊, 张冉冉, 方炜 2019 68 064210
Google Scholar
Wang L, Zhang R R, Fang W 2019 Acta Phys. Sin. 68 064210
Google Scholar
[23] Li Y B, Sinitskii A, Tour J M 2008 Nat. Mater. 7 966
Google Scholar
[24] Stuart S J, Tutein A B, Harrison J A 2000 J. Chem. Phys. 112 6472
Google Scholar
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