Effects of Oxidation on the Nanoscale Mechanisms of Crack Formation in Aluminum

Jarvis, Emily; Hayes, Robin L.; Carter, Emily A.

doi:10.1002/1439-7641(20010119)2:1<55::aid-cphc55>3.0.co;2-s

Cited by 43 publications

(35 citation statements)

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“…For example, our phenomenological cohesive relation is not based on a quantitative consideration of oxidation kinetics and the small-strain formulation neglects changes in the surface geometry due to slip steps which can give rise to roughness-induced crack closure. These limitations can be addressed through ab initio calculations such as those recently undertaken by Jarvis et al [46], which could provide the basis for a more accurate cohesive relation, and through a finite strain discrete dislocation formulation which accounts for geometry changes.…”

Section: Discussionmentioning

confidence: 99%

Discrete dislocation modeling of fatigue crack propagation

Deshpande

Needleman

Giessen³

2002

Acta Materialia

128

100

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Discrete dislocation modeling of fatigue crack propagation Deshpande, V.S.; Needleman, A.; van der Giessen, E.Published in: Acta Materialia DOI: 10.1016/S1359-6454(01)00377-9IMPORTANT NOTE: You are advised to consult the publisher's version (publisher's PDF) if you wish to cite from it. Please check the document version below. Document VersionPublisher's PDF, also known as Version of record Publication date: 2002Link to publication in University of Groningen/UMCG research database Citation for published version (APA): Deshpande, V. S., Needleman, A., & van der Giessen, E. (2002). Discrete dislocation modeling of fatigue crack propagation. Acta Materialia, 50(4), 831-846. [PII S1359-6454(01)00377-9]. https://doi.org/10.1016/S1359-6454(01)00377-9 Copyright Other than for strictly personal use, it is not permitted to download or to forward/distribute the text or part of it without the consent of the author(s) and/or copyright holder(s), unless the work is under an open content license (like Creative Commons).Take-down policy If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim.Downloaded from the University of Groningen/UMCG research database (Pure): http://www.rug.nl/research/portal. For technical reasons the number of authors shown on this cover page is limited to 10 maximum. AbstractAnalyses of the growth of a plane strain crack subject to remote mode I cyclic loading under small-scale yielding are carried out using discrete dislocation dynamics. Cracks along a metal-rigid substrate interface and in a single crystal are studied. The formulation is the same as that used to analyze crack growth under monotonic loading conditions, differing only in the remote stress intensity factor being a cyclic function of time. Plastic deformation is modeled through the motion of edge dislocations in an elastic solid with the lattice resistance to dislocation motion, dislocation nucleation, dislocation interaction with obstacles and dislocation annihilation being incorporated through a set of constitutive rules. An irreversible relation is specified between the opening traction and the displacement jump across a cohesive surface ahead of the initial crack tip in order to simulate cyclic loading in an oxidizing environment. The cyclic crack growth rate log(da/dN) versus applied stress intensity factor range log(⌬K I ) curve that emerges naturally from the solution of the boundary value problem shows distinct threshold and Paris law regimes. Paris law exponents in the range 4 to 8 are obtained for the parameters employed here. Furthermore, rather uniformly spaced slip bands corresponding to surface striations develop in the wakes of the propagating cracks. 

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Section: Discussionmentioning

confidence: 99%

Discrete dislocation modeling of fatigue crack propagation

Deshpande

Needleman

Giessen³

2002

Acta Materialia

128

100

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“…When comparing different materials and presuming that s coh ϰE and d n ϰb, the scaling implies that ⌬K eff th ϰE√b. On the other hand, for a fixed material, but with varying cohesive energy, due for example to chemical effects [36,37], ⌬K eff th ϰ√f n . We also find that varying the flow strength by a factor of two has no effect on the predicted crack growth rate in the lower Paris law regime.…”

Section: Discussionmentioning

confidence: 99%

Scaling of discrete dislocation predictions for near-threshold fatigue crack growth

2003

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Analyses of the growth of a plane strain crack subject to remote mode I cyclic loading under small scale yielding are carried out using discrete dislocation dynamics. Plastic deformation is modelled through the motion of edge dislocations in an elastic solid with the lattice resistance to dislocation motion, dislocation nucleation, dislocation interaction with obstacles and dislocation annihilation being incorporated through a set of constitutive rules. An irreversible relation is specified between the opening traction and the displacement jump across a cohesive surface ahead of the initial crack tip in order to simulate cyclic loading in an oxidizing environment. Calculations are carried out with different material parameters so that values of yield strength, cohesive strength and elastic moduli varying by factors of three to four are considered. The fatigue crack growth predictions are found to be insensitive to the yield strength of the material despite the number of dislocations and the plastic zone size varying by approximately an order of magnitude. The fatigue threshold scales with the fracture toughness of the purely elastic solid, with the experimentally observed linear scaling with Young's modulus an outcome when the cohesive strength scales with Young's modulus.

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“…Only when the initial electron density bridges the crack does it heal. 6 Yellow ͑blue͒ signifies high ͑low͒ electron density.…”

Section: ͑7͒mentioning

confidence: 99%

“…In order to obtain converged finite element results, the cohesive zone size must be resolved by the mesh; for brittle materials, the cohesive zone size is atomistic, making the calculation prohibitively expensive. 4 Nanometer scale quantum mechanical calculations have provided insight into cracking at the atomic level, [5][6][7][8] but their extrapolation to the macroscopic scale is fraught with difficulty. Indeed, orders-of-magnitude mismatch exist between atomistic predictions of cohesive strengths and critical opening displacements [9][10][11] and measurements of tensile strength in brittle materials obtained from spallation tests, 12 the latter of which are often employed in engineering simulations.…”

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confidence: 99%

Universal binding-energy relation for crystals that accounts for surface relaxation

2004

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We present a universal relation for crack surface cohesion including surface relaxation. Specifically, we analyze how N atomic planes respond to an opening displacement at its boundary, producing structurally relaxed surfaces. Via density-functional theory, we verify universality for metals ͑Al͒, ceramics (␣-Al 2 O 3 ), and semiconductors ͑Si͒. When the energy and opening displacement are scaled appropriately with respect to N, the uniaxial elastic constant, the relaxed surface energy, and the equilibrium interlayer spacing, all energydisplacement curves collapse onto a single universal curve. DOI: 10.1103/PhysRevB.69.172104 PACS number͑s͒: 61.50.Lt, 68.35.Ϫp, 71.15.Mb Macroscopic cohesive theories of fracture often involve empirical postulates on the shape and form of the cohesive law.1-3 While first principles simulations might be preferable, the typical size of engineering finite element models prohibits their direct application. In order to obtain converged finite element results, the cohesive zone size must be resolved by the mesh; for brittle materials, the cohesive zone size is atomistic, making the calculation prohibitively expensive.4 Nanometer scale quantum mechanical calculations have provided insight into cracking at the atomic level, 5-8 but their extrapolation to the macroscopic scale is fraught with difficulty. Indeed, orders-of-magnitude mismatch exist between atomistic predictions of cohesive strengths and critical opening displacements 9-11 and measurements of tensile strength in brittle materials obtained from spallation tests, 12 the latter of which are often employed in engineering simulations. The widely used universal binding energy relation ͑UBER͒ of Rose et al.13 describes cohesion between rigid surfaces based on atomic scale calculations, but application of the UBER to crack propagation simulations is hampered by its inability to capture the shape and absolute energies of cohesive laws for structurally relaxed surfaces.6,14 -16 Here, we address these difficulties by deriving a coarse-grained cohesive energy relation that accounts for structural relaxation of surfaces and exhibits a material-independent universal form.Nguyen and Ortiz recently suggested rescaling interlayer potentials to yield macroscopic cohesive laws. 17 Here we extend their work to account for surface relaxation and reconstruction. Specifically, we consider a perfect crystal acted upon by tensile stresses normal to a cleavage plane. The length scales under consideration range from mesoscopic ͑the dislocation free zone of a metal 18 ͒ to possibly macroscopic ͑brittle materials͒; we conservatively denote both scales as mesoscopic. We assume that atomic layers remain planar after deformation, so that the relative displacement of crystallographic layer i can be described by ␦ i ͑the interlayer spacing minus the equilibrium interlayer spacing, d͒ and that the crystal is periodic with a unit cell containing N atomic layers. We express the total energy per unit area of cleavage plane asis the local energy per layer of a ...

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Effects of Oxidation on the Nanoscale Mechanisms of Crack Formation in Aluminum

Cited by 43 publications

References 35 publications

Discrete dislocation modeling of fatigue crack propagation

Discrete dislocation modeling of fatigue crack propagation

Scaling of discrete dislocation predictions for near-threshold fatigue crack growth

Universal binding-energy relation for crystals that accounts for surface relaxation

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