Quantization of crack speeds in dynamic fracture of silicon: Multiparadigm ReaxFF modeling

Harvey Tang; Janet Rye; Markus J. Buehler; Adri Van Duin; William A. Goddard

Quantization of crack speeds in dynamic fracture of silicon: Multiparadigm ReaxFF modeling

Harvey Tang
, Janet Rye
, Markus J. Buehler
, Adri Van Duin
, William A. Goddard

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

Abstract

We report a study of dynamic cracking in a silicon single crystal in which the ReaxFF reactive force field is used for about 3,000 atoms near the crack tip while the other 100,000 atoms of the model system are described with a simple nonreactive force field. The ReaxFF is completely derived from quantum mechanical calculations of simple silicon systems without any empirical parameters. This model has been successfully used to study crack dynamics in silicon, capable of reproducing key experimental results such as orientation dependence of crack dynamics (Buehler et al., Phys. Rev. Lett., 2006). In this article, we focus on crack speeds as a function of loading and crack propagation mechanisms. We find that the steady state crack speed does not increase continuously with applied load, but instead jumps to a finite value immediately after the critical load, followed by a regime of slow increase. Our results quantitatively reproduce experimental observations of crack speeds during fracture in silicon along the (111) planes, confirming the existence of lattice trapping effects. We observe similar effects in the (110) crack direction.

Original language	English (US)
Title of host publication	Amorphous and Polycrystalline Thin-Film Silicon Science and Technology - 2006
Pages	149-154
Number of pages	6
State	Published - 2007
Event	2006 MRS Spring Meeting - San Francisco, CA, United States Duration: Apr 18 2006 → Apr 21 2006

Publication series

Name	Materials Research Society Symposium Proceedings
Volume	910
ISSN (Print)	0272-9172

Other

Other	2006 MRS Spring Meeting
Country/Territory	United States
City	San Francisco, CA
Period	4/18/06 → 4/21/06

All Science Journal Classification (ASJC) codes

Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering
General Materials Science

Cite this

@inproceedings{3da920b9637c4eceb751377025ee1f52,

title = "Quantization of crack speeds in dynamic fracture of silicon: Multiparadigm ReaxFF modeling",

abstract = "We report a study of dynamic cracking in a silicon single crystal in which the ReaxFF reactive force field is used for about 3,000 atoms near the crack tip while the other 100,000 atoms of the model system are described with a simple nonreactive force field. The ReaxFF is completely derived from quantum mechanical calculations of simple silicon systems without any empirical parameters. This model has been successfully used to study crack dynamics in silicon, capable of reproducing key experimental results such as orientation dependence of crack dynamics (Buehler et al., Phys. Rev. Lett., 2006). In this article, we focus on crack speeds as a function of loading and crack propagation mechanisms. We find that the steady state crack speed does not increase continuously with applied load, but instead jumps to a finite value immediately after the critical load, followed by a regime of slow increase. Our results quantitatively reproduce experimental observations of crack speeds during fracture in silicon along the (111) planes, confirming the existence of lattice trapping effects. We observe similar effects in the (110) crack direction.",

author = "Harvey Tang and Janet Rye and Buehler, \{Markus J.\} and \{Van Duin\}, Adri and Goddard, \{William A.\}",

year = "2007",

language = "English (US)",

isbn = "1558998667",

series = "Materials Research Society Symposium Proceedings",

pages = "149--154",

booktitle = "Amorphous and Polycrystalline Thin-Film Silicon Science and Technology - 2006",

note = "2006 MRS Spring Meeting ; Conference date: 18-04-2006 Through 21-04-2006",

}

Tang, H, Rye, J, Buehler, MJ, Van Duin, A & Goddard, WA 2007, Quantization of crack speeds in dynamic fracture of silicon: Multiparadigm ReaxFF modeling. in Amorphous and Polycrystalline Thin-Film Silicon Science and Technology - 2006. Materials Research Society Symposium Proceedings, vol. 910, pp. 149-154, 2006 MRS Spring Meeting, San Francisco, CA, United States, 4/18/06.

Quantization of crack speeds in dynamic fracture of silicon: Multiparadigm ReaxFF modeling. / Tang, Harvey; Rye, Janet; Buehler, Markus J. et al.
Amorphous and Polycrystalline Thin-Film Silicon Science and Technology - 2006. 2007. p. 149-154 (Materials Research Society Symposium Proceedings; Vol. 910).

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

TY - GEN

T1 - Quantization of crack speeds in dynamic fracture of silicon

T2 - 2006 MRS Spring Meeting

AU - Tang, Harvey

AU - Rye, Janet

AU - Buehler, Markus J.

AU - Van Duin, Adri

AU - Goddard, William A.

PY - 2007

Y1 - 2007

N2 - We report a study of dynamic cracking in a silicon single crystal in which the ReaxFF reactive force field is used for about 3,000 atoms near the crack tip while the other 100,000 atoms of the model system are described with a simple nonreactive force field. The ReaxFF is completely derived from quantum mechanical calculations of simple silicon systems without any empirical parameters. This model has been successfully used to study crack dynamics in silicon, capable of reproducing key experimental results such as orientation dependence of crack dynamics (Buehler et al., Phys. Rev. Lett., 2006). In this article, we focus on crack speeds as a function of loading and crack propagation mechanisms. We find that the steady state crack speed does not increase continuously with applied load, but instead jumps to a finite value immediately after the critical load, followed by a regime of slow increase. Our results quantitatively reproduce experimental observations of crack speeds during fracture in silicon along the (111) planes, confirming the existence of lattice trapping effects. We observe similar effects in the (110) crack direction.

AB - We report a study of dynamic cracking in a silicon single crystal in which the ReaxFF reactive force field is used for about 3,000 atoms near the crack tip while the other 100,000 atoms of the model system are described with a simple nonreactive force field. The ReaxFF is completely derived from quantum mechanical calculations of simple silicon systems without any empirical parameters. This model has been successfully used to study crack dynamics in silicon, capable of reproducing key experimental results such as orientation dependence of crack dynamics (Buehler et al., Phys. Rev. Lett., 2006). In this article, we focus on crack speeds as a function of loading and crack propagation mechanisms. We find that the steady state crack speed does not increase continuously with applied load, but instead jumps to a finite value immediately after the critical load, followed by a regime of slow increase. Our results quantitatively reproduce experimental observations of crack speeds during fracture in silicon along the (111) planes, confirming the existence of lattice trapping effects. We observe similar effects in the (110) crack direction.

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M3 - Conference contribution

AN - SCOPUS:34249944641

SN - 1558998667

SN - 9781558998667

T3 - Materials Research Society Symposium Proceedings

SP - 149

EP - 154

BT - Amorphous and Polycrystalline Thin-Film Silicon Science and Technology - 2006

Y2 - 18 April 2006 through 21 April 2006

ER -

Quantization of crack speeds in dynamic fracture of silicon: Multiparadigm ReaxFF modeling

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