Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension

Zhi Liang Pan; Yu Long Li; Qiu Ming Wei

doi:10.4028/www.scientific.net/SSP.139.83

Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension

Zhi Liang Pan, Yu Long Li, Qiu Ming Wei

School of Civil Aviation

University of North Carolina at Charlotte

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

Abstract

Using molecular dynamics (MD) simulation, we have investigated the mechanical properties and the microstructural evolution of nanocrystalline tantalum (NC-Ta, grain size from 3.25 nm to ~13.0 nm) under uniaxial tension. The results show the flow stress at a given offset strain decreases as the grain size is decreased within the grain size regime studied, implying an inverse Hall-Petch effect. A strain rate sensitivity of ~0.14, more than triple that of coarse-grain Ta, is derived from the simulation results. Twinning is regarded to be a secondary deformation mechanism based on the simulations. Similar to nanocrystalline iron, stress-induced phase transitions from body-centered cubic (BCC) to face-centered cubic (FCC) and hexagonal close-packed (HCP) structures take place locally during the deformation process, The maximum fraction of FCC atoms varies linearly with the tensile strength. We can thus conclude that a critical stress exists for the phase transition to occur. It is also observed that the higher the imposed strain rate, the further delayed is the phase transition. Such phase transitions are found to occur only at relatively low simulation temperatures, and are reversible with respect to stress.

Original language	English
Title of host publication	Theory, Modeling and Numerical Simulation of Multi-Physics Materials Behavior
Editors	Veena Tikare, Graeme E. Murch, Frederic Soisson, Jeung Ku Kang
Publisher	Trans Tech Publications Ltd
Pages	83-88
Number of pages	6
ISBN (Print)	9783908451563
DOIs	https://doi.org/10.4028/www.scientific.net/SSP.139.83
State	Published - 2008
Event	Symposium on Theory, Modeling and Numerical Simulation of Multiphysics Behavior, 2007 - Boston, United States Duration: 26 Nov 2007 → 30 Nov 2007

Publication series

Name	Solid State Phenomena
Volume	139
ISSN (Print)	1012-0394
ISSN (Electronic)	1662-9779

Conference

Conference	Symposium on Theory, Modeling and Numerical Simulation of Multiphysics Behavior, 2007
Country/Territory	United States
City	Boston
Period	26/11/07 → 30/11/07

Keywords

Deformation
Inter-grannular fracture
Molecular dynamics
Nanocrystalline tantalum

Access to Document

10.4028/www.scientific.net/SSP.139.83

Cite this

Pan, Z. L., Li, Y. L., & Wei, Q. M. (2008). Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension. In V. Tikare, G. E. Murch, F. Soisson, & J. K. Kang (Eds.), Theory, Modeling and Numerical Simulation of Multi-Physics Materials Behavior (pp. 83-88). (Solid State Phenomena; Vol. 139). Trans Tech Publications Ltd. https://doi.org/10.4028/www.scientific.net/SSP.139.83

@inproceedings{102b8262c5644432ada153b0f4b8a426,

title = "Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension",

abstract = "Using molecular dynamics (MD) simulation, we have investigated the mechanical properties and the microstructural evolution of nanocrystalline tantalum (NC-Ta, grain size from 3.25 nm to ~13.0 nm) under uniaxial tension. The results show the flow stress at a given offset strain decreases as the grain size is decreased within the grain size regime studied, implying an inverse Hall-Petch effect. A strain rate sensitivity of ~0.14, more than triple that of coarse-grain Ta, is derived from the simulation results. Twinning is regarded to be a secondary deformation mechanism based on the simulations. Similar to nanocrystalline iron, stress-induced phase transitions from body-centered cubic (BCC) to face-centered cubic (FCC) and hexagonal close-packed (HCP) structures take place locally during the deformation process, The maximum fraction of FCC atoms varies linearly with the tensile strength. We can thus conclude that a critical stress exists for the phase transition to occur. It is also observed that the higher the imposed strain rate, the further delayed is the phase transition. Such phase transitions are found to occur only at relatively low simulation temperatures, and are reversible with respect to stress.",

keywords = "Deformation, Inter-grannular fracture, Molecular dynamics, Nanocrystalline tantalum",

author = "Pan, {Zhi Liang} and Li, {Yu Long} and Wei, {Qiu Ming}",

note = "Publisher Copyright: {\textcopyright} (2008) Trans Tech Publications, Switzerland.; Symposium on Theory, Modeling and Numerical Simulation of Multiphysics Behavior, 2007 ; Conference date: 26-11-2007 Through 30-11-2007",

year = "2008",

doi = "10.4028/www.scientific.net/SSP.139.83",

language = "英语",

isbn = "9783908451563",

series = "Solid State Phenomena",

publisher = "Trans Tech Publications Ltd",

pages = "83--88",

editor = "Veena Tikare and Murch, {Graeme E.} and Frederic Soisson and Kang, {Jeung Ku}",

booktitle = "Theory, Modeling and Numerical Simulation of Multi-Physics Materials Behavior",

}

Pan, ZL, Li, YL & Wei, QM 2008, Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension. in V Tikare, GE Murch, F Soisson & JK Kang (eds), Theory, Modeling and Numerical Simulation of Multi-Physics Materials Behavior. Solid State Phenomena, vol. 139, Trans Tech Publications Ltd, pp. 83-88, Symposium on Theory, Modeling and Numerical Simulation of Multiphysics Behavior, 2007, Boston, United States, 26/11/07. https://doi.org/10.4028/www.scientific.net/SSP.139.83

Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension. / Pan, Zhi Liang; Li, Yu Long; Wei, Qiu Ming.
Theory, Modeling and Numerical Simulation of Multi-Physics Materials Behavior. ed. / Veena Tikare; Graeme E. Murch; Frederic Soisson; Jeung Ku Kang. Trans Tech Publications Ltd, 2008. p. 83-88 (Solid State Phenomena; Vol. 139).

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

TY - GEN

T1 - Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension

AU - Pan, Zhi Liang

AU - Li, Yu Long

AU - Wei, Qiu Ming

N1 - Publisher Copyright: © (2008) Trans Tech Publications, Switzerland.

PY - 2008

Y1 - 2008

N2 - Using molecular dynamics (MD) simulation, we have investigated the mechanical properties and the microstructural evolution of nanocrystalline tantalum (NC-Ta, grain size from 3.25 nm to ~13.0 nm) under uniaxial tension. The results show the flow stress at a given offset strain decreases as the grain size is decreased within the grain size regime studied, implying an inverse Hall-Petch effect. A strain rate sensitivity of ~0.14, more than triple that of coarse-grain Ta, is derived from the simulation results. Twinning is regarded to be a secondary deformation mechanism based on the simulations. Similar to nanocrystalline iron, stress-induced phase transitions from body-centered cubic (BCC) to face-centered cubic (FCC) and hexagonal close-packed (HCP) structures take place locally during the deformation process, The maximum fraction of FCC atoms varies linearly with the tensile strength. We can thus conclude that a critical stress exists for the phase transition to occur. It is also observed that the higher the imposed strain rate, the further delayed is the phase transition. Such phase transitions are found to occur only at relatively low simulation temperatures, and are reversible with respect to stress.

AB - Using molecular dynamics (MD) simulation, we have investigated the mechanical properties and the microstructural evolution of nanocrystalline tantalum (NC-Ta, grain size from 3.25 nm to ~13.0 nm) under uniaxial tension. The results show the flow stress at a given offset strain decreases as the grain size is decreased within the grain size regime studied, implying an inverse Hall-Petch effect. A strain rate sensitivity of ~0.14, more than triple that of coarse-grain Ta, is derived from the simulation results. Twinning is regarded to be a secondary deformation mechanism based on the simulations. Similar to nanocrystalline iron, stress-induced phase transitions from body-centered cubic (BCC) to face-centered cubic (FCC) and hexagonal close-packed (HCP) structures take place locally during the deformation process, The maximum fraction of FCC atoms varies linearly with the tensile strength. We can thus conclude that a critical stress exists for the phase transition to occur. It is also observed that the higher the imposed strain rate, the further delayed is the phase transition. Such phase transitions are found to occur only at relatively low simulation temperatures, and are reversible with respect to stress.

KW - Deformation

KW - Inter-grannular fracture

KW - Molecular dynamics

KW - Nanocrystalline tantalum

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M3 - 会议稿件

AN - SCOPUS:84954450151

SN - 9783908451563

T3 - Solid State Phenomena

SP - 83

EP - 88

BT - Theory, Modeling and Numerical Simulation of Multi-Physics Materials Behavior

A2 - Tikare, Veena

A2 - Murch, Graeme E.

A2 - Soisson, Frederic

A2 - Kang, Jeung Ku

PB - Trans Tech Publications Ltd

T2 - Symposium on Theory, Modeling and Numerical Simulation of Multiphysics Behavior, 2007

Y2 - 26 November 2007 through 30 November 2007

ER -

Molecular dynamics simulation of nanocrystalline tantalumunder uniaxial tension

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Keywords

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