Refining Grains of Metals through Plastic Deformation: Toward Grain Size Limits

Li, Xiuyan; Lu, K.

doi:10.1021/accountsmr.0c00075

Cited by 16 publications

(7 citation statements)

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“…It is known that severe plastic strain leads to grain refinement. [ 19,44,45 ] Here, the FCC grain size decreases after yielding, and its final size is close to the BCC grain size. Finally, the comparison of the stress−strain curve obtained through theoretical model calculation and experiments is shown in Figure 8b.…”

Section: Resultsmentioning

confidence: 76%

Modeling and Analysis of Yielding and Strain Hardening in Metastable High‐Entropy Alloys

Ren

Fang

et al. 2021

Physica Status Solidi (b)

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Metastable dual‐phase high‐entropy alloys (HEAs) have become an attractive paradigm as structural materials due to their outstanding mechanical properties compared with single‐phase HEAs, which originate from the multiple strengthening mechanisms. Herein, a theoretical model is established by integrating the effects of lattice distortion, dislocation, grain boundary, and phase transformation, to study the mechanical responses of metastable HEAs during uniaxial tensile deformation. The results show the contribution of various mechanisms to the strength, and strain hardening can be determined quantitatively. In particular, the face‐centered cubic (FCC) to body‐centered cubic (BCC) phase transformation would dominate the flow stress with plastic strain to exceed 6%, due to the strong phase interface strengthening and the formation of hard BCC phase. This work provides a microstructure‐based constitutive model for predicting the flow stress and strain hardening properties of metastable HEAs.

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Section: Resultsmentioning

confidence: 76%

Modeling and Analysis of Yielding and Strain Hardening in Metastable High‐Entropy Alloys

Ren

Fang

et al. 2021

Physica Status Solidi (b)

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“…GB relaxation is observed not only in Cu, but also in other FCC metals with higher stacking fault energies (such as Ni and Al) and metals with lower stacking fault energies (Ag). The GB relaxation found in the nanograined metals indicated that below a critical grain size, the dislocation motion changes and interacting with dislocations will also change the GB state simultaneously [18,19]. The extensivelyexisting GB structure modification and GB relaxation in nanograined metals prepared by plastic deformation can be utilized to develop stable nanostructured metals and alloys for high temperature applications.…”

Section: Gb Relaxation (< 70 Nm)mentioning

confidence: 99%

Grain boundary evolution in nanograined metals: from relaxation to Schwarzation

2022

IOP Conf. Ser.: Mater. Sci. Eng.

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High density of grain boundaries (GBs) in nanograined metals may become unstable and evolve in various ways such as migration, sliding, or relaxation under thermal or mechanical stimuli. In this report, we will present our recent studies on structural evolution of GBs in nanograined Cu during intensive plastic deformation. As the grain size decreased below 200 nm, GB migration become obvious assisted by dislocation activities. Below 70 nm, accompanied by a transition in dominant deformation mechanism from full dislocations to partials, GB migration decays gradually, while the GB structures relax into lower energy states through their interactions with partials. The population of low-energy GBs increases with a decreasing grain size. Below 10 nm, further refinement of grains results in a violent structural evolution of the GB network into a 3-dimensional periodic minimal surface structure, Schwarz-D, through a phase-transformation-like process, which is termed as Schwarzation.

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“…polymers and metals, with the critical lengths of polymers passing the entanglement limit and the metal grain sizes over several nm. 1,2 As model systems for the studies of general material physics, granular materials, composed of densely packed nano-or macro-scale particles, demonstrate unique impact-and shock-resistant properties that are highly dependent on the sizes, morphologies and surface structures of the building units. [3][4][5] When their sizes approach the tens of nanometer scale, the dynamics of particles can be manipulated by the complex interactions among the particles in their assemblies, giving rise to unexpected and oen exceptional mechanical performances.…”

Section: Introductionmentioning

confidence: 99%