Influence of grain boundary structure on interfacial fracture under tensile loading: Cohesive zone model informed by atomistic simulations

I. Adlakha; Kiran Solanki; M. A. Tschopp

Influence of grain boundary structure on interfacial fracture under tensile loading: Cohesive zone model informed by atomistic simulations

I. Adlakha, Kiran Solanki, M. A. Tschopp

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

Abstract

Grain boundary (GB) structure significantly contributes to the properties of polycrystalline materials. The objective of this work is to quantify the role of GB structure and energy on fracture behavior under tensile loading. Molecular dynamic (MD) calculations were performed for five aluminum (At) bicrystals with 〈100〉 symmetric tilt axes. The cohesive zone model (CZM) was used to analyze the fracture process. The simulation results indicate that the presence of certain GB structural units result in lower yield strengths and asymmetric crack growth behavior. The atomic traction-separation results suggest a strong correlation between cohesive energy of the interface and the GB energy. Finally, a framework is presented to characterize interfacial fracture of GBs through continuum interface separation constitutive laws that are informed from MD simulations.

Original language	English (US)
Title of host publication	TMS 2013 - 142nd Annual Meeting and Exhibition, Supplemental Proceedings
Subtitle of host publication	Linking Science and Technology for Global Solutions
Pages	753-758
Number of pages	6
State	Published - Apr 25 2013
Event	142nd Annual Meeting and Exhibition: Linking Science and Technology for Global Solutions, TMS 2013 - San Antonio, TX, United States Duration: Mar 3 2013 → Mar 7 2013

Publication series

Name	TMS Annual Meeting

Other

Other	142nd Annual Meeting and Exhibition: Linking Science and Technology for Global Solutions, TMS 2013
Country/Territory	United States
City	San Antonio, TX
Period	3/3/13 → 3/7/13

Keywords

Cohesive zone
Crack growth
Grain boundary
Interfacial fracture

ASJC Scopus subject areas

Condensed Matter Physics
Mechanics of Materials
Metals and Alloys

Cite this

Influence of grain boundary structure on interfacial fracture under tensile loading: Cohesive zone model informed by atomistic simulations. / Adlakha, I.; Solanki, Kiran; Tschopp, M. A.
TMS 2013 - 142nd Annual Meeting and Exhibition, Supplemental Proceedings: Linking Science and Technology for Global Solutions. 2013. p. 753-758 (TMS Annual Meeting).

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

Adlakha, I, Solanki, K & Tschopp, MA 2013, Influence of grain boundary structure on interfacial fracture under tensile loading: Cohesive zone model informed by atomistic simulations. in TMS 2013 - 142nd Annual Meeting and Exhibition, Supplemental Proceedings: Linking Science and Technology for Global Solutions. TMS Annual Meeting, pp. 753-758, 142nd Annual Meeting and Exhibition: Linking Science and Technology for Global Solutions, TMS 2013, San Antonio, TX, United States, 3/3/13.

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abstract = "Grain boundary (GB) structure significantly contributes to the properties of polycrystalline materials. The objective of this work is to quantify the role of GB structure and energy on fracture behavior under tensile loading. Molecular dynamic (MD) calculations were performed for five aluminum (At) bicrystals with 〈100〉 symmetric tilt axes. The cohesive zone model (CZM) was used to analyze the fracture process. The simulation results indicate that the presence of certain GB structural units result in lower yield strengths and asymmetric crack growth behavior. The atomic traction-separation results suggest a strong correlation between cohesive energy of the interface and the GB energy. Finally, a framework is presented to characterize interfacial fracture of GBs through continuum interface separation constitutive laws that are informed from MD simulations.",

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T2 - 142nd Annual Meeting and Exhibition: Linking Science and Technology for Global Solutions, TMS 2013

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PY - 2013/4/25

Y1 - 2013/4/25

N2 - Grain boundary (GB) structure significantly contributes to the properties of polycrystalline materials. The objective of this work is to quantify the role of GB structure and energy on fracture behavior under tensile loading. Molecular dynamic (MD) calculations were performed for five aluminum (At) bicrystals with 〈100〉 symmetric tilt axes. The cohesive zone model (CZM) was used to analyze the fracture process. The simulation results indicate that the presence of certain GB structural units result in lower yield strengths and asymmetric crack growth behavior. The atomic traction-separation results suggest a strong correlation between cohesive energy of the interface and the GB energy. Finally, a framework is presented to characterize interfacial fracture of GBs through continuum interface separation constitutive laws that are informed from MD simulations.

AB - Grain boundary (GB) structure significantly contributes to the properties of polycrystalline materials. The objective of this work is to quantify the role of GB structure and energy on fracture behavior under tensile loading. Molecular dynamic (MD) calculations were performed for five aluminum (At) bicrystals with 〈100〉 symmetric tilt axes. The cohesive zone model (CZM) was used to analyze the fracture process. The simulation results indicate that the presence of certain GB structural units result in lower yield strengths and asymmetric crack growth behavior. The atomic traction-separation results suggest a strong correlation between cohesive energy of the interface and the GB energy. Finally, a framework is presented to characterize interfacial fracture of GBs through continuum interface separation constitutive laws that are informed from MD simulations.

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KW - Interfacial fracture

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Influence of grain boundary structure on interfacial fracture under tensile loading: Cohesive zone model informed by atomistic simulations

Abstract

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Keywords

ASJC Scopus subject areas

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