A geometric approach to modeling microstructurally small fatigue crack formation: II. Physically based modeling of microstructure-dependent slip localization and actuation of the crack nucleation mechanism in AA 7075-T651

Hochhalter, Jacob; Littlewood, David John; Christ, Robert J.; Veilleux, Michael; Bozek, J. E.; Ingraffea, Anthony R.; Maniatty, Antoinette M.

doi:10.1088/0965-0393/18/4/045004

Cited by 92 publications

(101 citation statements)

References 43 publications

(80 reference statements)

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“…Fatigue indicator parameters (FIPs) were employed in [51] in fatigue studies on a peak-aged aluminium alloy in which fatigue crack nucleation is premised to be preceded by the development of persistent slip local to a non-shearable cracked particle inclusion. Fatigue cracks are thought to develop more rapidly in this material than in those for which PSBs do develop, and typically, in the experimental study, the regions of slip localisation were found to be quite diffuse.…”

Section: Nucleation Criteria and Microcracksmentioning

confidence: 99%

Fatigue crack nucleation: Mechanistic modelling across the length scales

Dunne

2014

Current Opinion in Solid State and Materials Science

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This paper presents an assessment of recent literature on the mechanistic understanding of fatigue crack nucleation and the associated modelling techniques employed. In particular, the important roles of (a) slip localisation and persistent slip band formation, (b) grain boundaries, slip transfer and interfaces, (c) microtexture and twins, and (d) nucleation criteria and microcracks are addressed in the context of the three key modelling techniques of crystal plasticity (CP), discrete dislocation (DD) plasticity and molecular dynamics (MD) where appropriate. In addition, the need for computational fatigue crack nucleation methodologies which incorporate mechanistic understanding is addressed. Key challenges identified include (i) the overall need for multiscale models for fatigue crack nucleation which are continuum-based but mechanistically informed; (ii) full (3D) crystal slip models to capture slip localisation at a DD level; (iii) MD modelling methodologies for slip transfer to inform DD models; and (iv) rigorously validated dislocation structure models at the DD and CP levels.

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Section: Nucleation Criteria and Microcracksmentioning

confidence: 99%

Fatigue crack nucleation: Mechanistic modelling across the length scales

Dunne

2014

Current Opinion in Solid State and Materials Science

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“…Similar to the studies of nickel-based alloys, detailed three-dimensional finite element models of aluminum 7075-T651 have been generated to predict the initiation of cracking at the microstructural scale (Hochhalter, 2010). To better understand the slip accumulation during cyclic loading that precedes nucleation events, these finite element models were generated using observed microstructural data that included the configuration and location of constituent particles and grain microstructural details.…”

Section: Modeling Near-crack-tip Plasticity At the Micro Scalementioning

confidence: 99%

Modeling Near-Crack-Tip Plasticity at Nano- to Micro- Scales

Glaessgen

Saether²,

Hochhalter

et al. 2010

51st AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference

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Several efforts that are aimed at understanding the plastic deformation mechanisms related to crack propagation at the nano-, meso-and micro-length scales including atomistic simulation, discrete dislocation plasticity, strain gradient plasticity and crystal plasticity are discussed. The paper focuses on discussion of newly developed methodologies and their application to understanding damage processes in aluminum and its alloys. Examination of plastic mechanisms as a function of increasing length scale illustrates increasingly complex phenomena governing plasticity.

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“…By incorporating models for slip accumulation, a relationship between plastic exhaustion and crack growth can be computed 17 .…”

Section: Damage Accumulation In Aluminum Microstructuresmentioning
confidence: 99%

“…The discrepancy between simulations and experiments has attracted considerable attention among researchers because it prevents the reliable and accurate modeling of fracture in particular and puts doubt on the reliability of the atomistic simulations in general 17,31 . Most likely, the source of this discrepancy is related to the very different length (nanometers vs. millimeters) and time (nanoseconds vs. seconds) scales at which simulations and experiments are usually performed.…”

Section: Atomistic Simulation Of Crack Growthmentioning
confidence: 99%

An Overview of Innovative Strategies for Fracture Mechanics at NASA Langley Research Center
Ransom
¹
,
Glaessgen²,
Ratcliffe
³

2010
51st AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference
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Engineering fracture mechanics has played a vital role in the development and certification of virtually every aerospace vehicle that has been developed since the mid-20 th century. NASA Langley Research Center's Durability, Damage Tolerance and Reliability Branch has contributed to the development and implementation of many fracture mechanics methods aimed at predicting and characterizing damage in both metallic and composite materials. This paper presents a selection of computational, analytical and experimental strategies that have been developed by the branch for assessing damage growth under monotonic and cyclic loading and for characterizing the damage tolerance of aerospace structures.

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A geometric approach to modeling microstructurally small fatigue crack formation: II. Physically based modeling of microstructure-dependent slip localization and actuation of the crack nucleation mechanism in AA 7075-T651

Cited by 92 publications

References 43 publications

Fatigue crack nucleation: Mechanistic modelling across the length scales

Fatigue crack nucleation: Mechanistic modelling across the length scales

Modeling Near-Crack-Tip Plasticity at Nano- to Micro- Scales

An Overview of Innovative Strategies for Fracture Mechanics at NASA Langley Research Center

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