Dislocation Reaction Mechanism for Enhanced Strain Hardening in Crystal Nano-Indentations

Armstrong, Ronald W.; Elban, W. L.

doi:10.3390/cryst10010009

Cited by 7 publications

(5 citation statements)

References 27 publications

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“…Goel, Cross, Stukowski, Gamsjäger, Beake and Agrawal demonstrated that a[100] reacted dislocation line lengths formed at the earliest stages of deformation in simulations of nano-indentations made in tungsten crystals [33]. Armstrong and Elban have reported comparative plastic strain hardening behaviors in post-pop-in plastic deformation at nano-indents and in drawn wire and micro-pillar deformation tests [34].…”

Section: Discussionmentioning

confidence: 99%

Metal Crystal/Polycrystal Plasticity and Strengths

Armstrong

2022

Metals

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A brief historical sketch is given of Taylor’s dislocation density-based model description, leading to the prediction of a parabolic, tensile, stress–strain curve for the plastic deformation of aluminum. The present focus is on additional results or analyses obtained on the subject for crystal/polycrystal strain hardening. Our current understanding of such material behavior is attributed to post-Taylor descriptions of sequential deformation stages in stress–strain measurements that are closely tied to specific dislocation interaction and reaction mechanisms. A schematic comparison is given for individual face-centered cubic (fcc), body-centered cubic (bcc), and hexagonal close-packed (hcp) crystal curves and to related strength properties determined for individual crystals and polycrystalline material. For the fcc case, an example sessile dislocation reaction is described based on a stereographic projection. Then, quantitative constitutive-relation-based assessments are presented for the tensile strain hardening leading to the plastic instability behaviors of copper and tantalum materials.

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Section: Discussionmentioning

confidence: 99%

Metal Crystal/Polycrystal Plasticity and Strengths

Armstrong

2022

Metals

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“…The test method was employed to probe the material anisotropic elastic deformation behavior through testing the diamond pyramid hardness of (100), (110), and (111) crystal surfaces. The research relates to reference [20] in which a comparison was made between the experiment and simulation of nano-indentations in (111) and (100) α-iron crystal surfaces. At an opposite dimensional scale, an important civil engineering connection spanning nano-to macro-size dimensions was provided by a comparison of the ultrafine steel wire measurements described for the drawn micro-wire strengths presented in Figure 2 and the comprehensive description by Ono [39] of steel wire materials employed in historical and current transportation bridge constructions.…”

Section: Discussionmentioning

confidence: 99%

“…Close examination of the deviation from the labeled d 2 dependence in Figure 1 shows that an increasing hardness applies for a smaller indentation size. Calculations of the stress-strain behaviors both at the onset of plastic yielding and follow-on nano-indentation strain hardening behaviors have been reported very recently for NaCl, MgO, and copper crystals [18], tungsten crystals [19], ammonium perchlorate, and α-iron crystals [20]. Beyond the well-established determination of very high flow stress levels for initial plastic yielding, whether gradual or of pop-in type, the plastic strain hardening behavior has also been shown to be exceptionally high.…”

Section: Elastic Plastic and Cracking Aspects Of Crystal Nano-indenmentioning

confidence: 99%

Crystal Strengths at Micro- and Nano-Scale Dimensions

Armstrong

Elban

2020

Crystals

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Higher strength levels, achieved for dimensionally-smaller micro- and nano-scale materials or material components, such as MEMS devices, are an important enabler of a broad range of present-day engineering devices and structures. Beyond such applications, there is an important effort to understand the dislocation mechanics basis for obtaining such improved strength properties. Four particular examples related to these issues are described in the present report: (1) a compilation of nano-indentation hardness measurements made on silicon crystals spanning nano- to micro-scale testing; (2) stress–strain measurements made on iron and steel materials at micro- to nano-crystal (grain size) dimensions; (3) assessment of small dislocation pile-ups relating to Griffith-type fracture stress vs. crack-size calculations for cleavage fracturing of α-iron; and (4) description of thermally-dependent strain rate sensitivities for grain size strengthening and weakening for macro- to micro- to nano-polycrystalline copper and nickel materials.

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“…The parameter μ φ is the atomistically resolved friction coefficient. The coefficient quantifies the slip non-planarity caused by screw-dislocations, cross-slip, dislocation bowing and other mechanisms [21–23]. Among the common features encapsulated in μ φ are the existence of non-glide shear stress and the break-down of Schmid's Law.…”

Section: Image Of Texture-distorted Reference Systemmentioning

confidence: 99%

Another perspective on elastic and plastic anisotropy of textured metals

Zubelewicz

2021

Proc. R. Soc. A.

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In textured metals, the elastic directionality reflects the crystallographic organization, while the plastic flow follows the preferential pathways of deformation beyond the elastic limit. In here, the elastic and plastic anisotropies are characterized by two observers. One of them is immersed into the material and, while there, is unaware of the texture-induced reorganizations, still, is in a position to detect elastic distortions. Another observer is located outside the material, monitors the elastic strain too and realizes that texture makes the elastic responses directional. The externally measured elastic strain will be called the texture strain. The key idea is to determine the transformation rules that correlate the elastic strains seen by the two observers. In what follows, the rules are derived by projecting the texture-distorted basis onto the basis of the external observations. It turns out that the rules reproduce directionality of elastic properties and include constraints that result from the limits imposed by the yield stress. The elastic anisotropy is linked to the strain that is free of the plasticity-induced constraints. By contrast, the constraints enable complete characterization of the plastic flow directionality. The concept is derived in the framework of tensor representations discussed in the electronic supplementary material.

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Dislocation Reaction Mechanism for Enhanced Strain Hardening in Crystal Nano-Indentations

Cited by 7 publications

References 27 publications

Metal Crystal/Polycrystal Plasticity and Strengths

Metal Crystal/Polycrystal Plasticity and Strengths

Crystal Strengths at Micro- and Nano-Scale Dimensions

Another perspective on elastic and plastic anisotropy of textured metals

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