Driving Forces on Dislocations - An Analytical and Finite Element Study

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Standard

Driving Forces on Dislocations - An Analytical and Finite Element Study. / Kolednik, Otmar; Ochensberger, Walter; Predan, Jozef et al.
in: International journal of solids and structures, Jahrgang 190.2020, Nr. May, 09.11.2019, S. 181-198.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

Vancouver

Kolednik O, Ochensberger W, Predan J, Fischer FD. Driving Forces on Dislocations - An Analytical and Finite Element Study. International journal of solids and structures. 2019 Nov 9;190.2020(May):181-198. Epub 2019 Nov 9. doi: 10.1016/j.ijsolstr.2019.11.008

Author

Kolednik, Otmar ; Ochensberger, Walter ; Predan, Jozef et al. / Driving Forces on Dislocations - An Analytical and Finite Element Study. in: International journal of solids and structures. 2019 ; Jahrgang 190.2020, Nr. May. S. 181-198.

Bibtex - Download

@article{ba412e748d80486199664ec3b0f6bb67,
title = "Driving Forces on Dislocations - An Analytical and Finite Element Study",
abstract = "The current paper discusses concepts for implementing distinct edge dislocations into continua. Such dislocation models are successful, if they correctly predict both the stress- and displacement field around the dislocation line and the driving force on the dislocation in the presence of an external stress state. In addition, it is desired to realize the dislocation model by finite element programs. It is shown that the dislocation models available in literature do not fulfill these conditions, since they do not yield the correct driving force terms. Additional defect structures are investigated in order to work out a more successful dislocation model. Several methods are applied to derive the driving force on the dislocation for each model, (i) the configurational force concept, (ii) a thermodynamic concept based on the interaction energy, (iii) a relationship based on conservation integrals and the dislocation density. The results are compared to the classical Peach-Koehler solution. Two different procedures are worked out to correctly model a single edge dislocation, a numerically very simple method in form of two strips with prescribed eigenstrain components, which are considered consecutively, and a numerically more sophisticated concept, denominated as “cut-displace-glue” procedure.",
author = "Otmar Kolednik and Walter Ochensberger and Jozef Predan and Franz-Dieter Fischer",
year = "2019",
month = nov,
day = "9",
doi = "10.1016/j.ijsolstr.2019.11.008",
language = "English",
volume = "190.2020",
pages = "181--198",
journal = "International journal of solids and structures",
issn = "0020-7683",
publisher = "Elsevier",
number = "May",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Driving Forces on Dislocations - An Analytical and Finite Element Study

AU - Kolednik, Otmar

AU - Ochensberger, Walter

AU - Predan, Jozef

AU - Fischer, Franz-Dieter

PY - 2019/11/9

Y1 - 2019/11/9

N2 - The current paper discusses concepts for implementing distinct edge dislocations into continua. Such dislocation models are successful, if they correctly predict both the stress- and displacement field around the dislocation line and the driving force on the dislocation in the presence of an external stress state. In addition, it is desired to realize the dislocation model by finite element programs. It is shown that the dislocation models available in literature do not fulfill these conditions, since they do not yield the correct driving force terms. Additional defect structures are investigated in order to work out a more successful dislocation model. Several methods are applied to derive the driving force on the dislocation for each model, (i) the configurational force concept, (ii) a thermodynamic concept based on the interaction energy, (iii) a relationship based on conservation integrals and the dislocation density. The results are compared to the classical Peach-Koehler solution. Two different procedures are worked out to correctly model a single edge dislocation, a numerically very simple method in form of two strips with prescribed eigenstrain components, which are considered consecutively, and a numerically more sophisticated concept, denominated as “cut-displace-glue” procedure.

AB - The current paper discusses concepts for implementing distinct edge dislocations into continua. Such dislocation models are successful, if they correctly predict both the stress- and displacement field around the dislocation line and the driving force on the dislocation in the presence of an external stress state. In addition, it is desired to realize the dislocation model by finite element programs. It is shown that the dislocation models available in literature do not fulfill these conditions, since they do not yield the correct driving force terms. Additional defect structures are investigated in order to work out a more successful dislocation model. Several methods are applied to derive the driving force on the dislocation for each model, (i) the configurational force concept, (ii) a thermodynamic concept based on the interaction energy, (iii) a relationship based on conservation integrals and the dislocation density. The results are compared to the classical Peach-Koehler solution. Two different procedures are worked out to correctly model a single edge dislocation, a numerically very simple method in form of two strips with prescribed eigenstrain components, which are considered consecutively, and a numerically more sophisticated concept, denominated as “cut-displace-glue” procedure.

UR - http://www.scopus.com/inward/record.url?scp=85076037841&partnerID=8YFLogxK

U2 - 10.1016/j.ijsolstr.2019.11.008

DO - 10.1016/j.ijsolstr.2019.11.008

M3 - Article

VL - 190.2020

SP - 181

EP - 198

JO - International journal of solids and structures

JF - International journal of solids and structures

SN - 0020-7683

IS - May

ER -