A theoretical analysis of dislocation emission from an elliptical blunt crack tip in nanocrystalline solid

AbstractTheories of toughness of materials depend on an understanding of the characteristic instabilities of the crack tip, and their possible interactions. In this paper we examine the effect of dislocation emission on subsequent cleavage of a crack and on further dislocation emission. The work is an extension of the previously published Lattice Greens Function methodology[1, 2, 3]. We have developed a Cavity Greens Function describing a blunt crack and used it to study the effect of crack blunting under a range of different force laws. As the crack is blunted, we find a small but noticeable increase in the crack loading needed to propagate the crack. This effect may be of importance in materials where a dislocation source near the crack tip in a brittle material causes the crack to absorb anti-shielding dislocations, and thus cause a blunting of the crack. It is obviously also relevant to cracks in more ductile materials where the crack itself may emit dislocations.

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The Ductile versus Brittle Fracture Behavior Assessed by the Competition between Dislocation Emission and Cleavage at Blunt Crack Tip

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.274-276.135 ◽

2004 ◽

Vol 274-276 ◽

pp. 135-140 ◽

Cited By ~ 2

Author(s):

Ming Xin Huang ◽

Zhong Hua Li

Keyword(s):

Brittle Fracture ◽

Fracture Behavior ◽

Crack Tip ◽

Dislocation Emission ◽

Blunt Crack

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Effect of special rotational deformation on dislocation emission from a semielliptical blunt crack tip in nanocrystalline solids

Journal of Materials Research ◽

10.1557/jmr.2012.405 ◽

2013 ◽

Vol 28 (6) ◽

pp. 798-805 ◽

Cited By ~ 5

Author(s):

Min Yu ◽

Qihong Fang ◽

Hui Feng ◽

Youwen Liu

Keyword(s):

Crack Tip ◽

Dislocation Emission ◽

Blunt Crack ◽

Rotational Deformation ◽

Image Position ◽

Nanocrystalline Solids

Abstract

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Effect of Crack Blunting on Subsequent Crack Propagation

MRS Proceedings ◽

10.1557/proc-408-237 ◽

1995 ◽

Vol 408 ◽

Author(s):

J. Schiøtz ◽

A. E. Carlsson ◽

L. M. Canel ◽

Robb Thomson

Keyword(s):

Crack Propagation ◽

Brittle Material ◽

Crack Tip ◽

Dislocation Emission ◽

Dislocation Source ◽

Blunt Crack ◽

Ductile Materials ◽

Noticeable Increase ◽

Greens Function ◽

Crack Blunting

AbstractTheories of toughness of materials depend on an understanding of the characteristic instabilities of the crack tip, and their possible interactions. In this paper we examine the effect of dislocation emission on subsequent cleavage of a crack and on further dislocation emission. The work is an extension of the previously published Lattice Greens Function methodology[l, 2, 3]. We have developed a Cavity Greens Function describing a blunt crack and used it to study the effect of crack blunting under a range of different force laws. As the crack is blunted, we find a small but noticeable increase in the crack loading needed to propagate the crack. This effect may be of importance in materials where a dislocation source near the crack tip in a brittle material causes the crack to absorb anti-shielding dislocations, and thus cause a blunting of the crack. It is obviously also relevant to cracks in more ductile materials where the crack itself may emit dislocations.

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Atomistic Study of Cleavage and Dislocation Emission in NiAl

MRS Proceedings ◽

10.1557/proc-364-389 ◽

1994 ◽

Vol 364 ◽

Cited By ~ 4

Author(s):

M. Ludwig ◽

P. Gumbsch

Keyword(s):

Finite Element ◽

Mixed Mode ◽

Crack Tip ◽

Mode I ◽

Crack Plane ◽

Dislocation Emission ◽

Dislocation Generation ◽

Embedded Atom ◽

Atomistic Study ◽

Eam Potential

AbstractThe atomistic processes during fracture of NiAl are studied using a new embedded atom (EAM) potential to describe the region near the crack tip. To provide the atomistically modeled crack tip region with realistic boundary conditions, a coupled finite element - atomistic (FEAt) technique [1] is employed. In agreement with experimental observations, perfectly brittle cleavage is observed for the (110) crack plane. In contrast, cracks on the (100) plane either follow a zig-zag path on (110) planes, or emit dislocations. Dislocation generation is studied in more detail under mixed mode I/II loading conditions.

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