Work-Hardening Induced Tensile Ductility of Bulk Metallic Glasses via High-Pressure Torsion

Joo, Soo Hyun; Pi, Dong-Hai; Setyawan, Albertus D.; Kato, Hidemi; Janeček, Miloš; Kim, Yong Chan; Lee, Sunghak; Kim, Hyoung Seop

doi:10.1038/srep09660

Cited by 84 publications

(20 citation statements)

References 48 publications

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“…On the other hand, only a few effective methods for improving the tensile ductility of BMGs have been developed so far. These methods, which also generate heterogeneous microstructures, include cold rolling 19,20 , high-pressure torsion 21 and surface mechanical attrition 22 . Although the effectiveness of heterogeneous microstructures for enhancing the tensile ductility of BMGs has been established 19–22 , the limits of this approach have not been fully evaluated yet.…”

Section: Introductionmentioning

confidence: 99%

Ductile bulk metallic glass by controlling structural heterogeneities

Scudino

Bian

Shahabi

et al. 2018

Sci Rep

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A prerequisite to utilize the full potential of structural heterogeneities for improving the room-temperature plastic deformation of bulk metallic glasses (BMGs) is to understand their interaction with the mechanism of shear band formation and propagation. This task requires the ability to artificially create heterogeneous microstructures with controlled morphology and orientation. Here, we analyze the effect of the designed heterogeneities generated by imprinting on the tensile mechanical behavior of the Zr52.5Ti5Cu18Ni14.5Al10 BMG by using experimental and computational methods. The imprinted material is elastically heterogeneous and displays anisotropic mechanical properties: strength and ductility increase with increasing the loading angle between imprints and tensile direction. This behavior occurs through shear band branching and their progressive rotation. Molecular dynamics and finite element simulations indicate that shear band branching and rotation originates at the interface between the heterogeneities, where the characteristic atomistic mechanism responsible for shear banding in a homogeneous glass is perturbed.

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Section: Introductionmentioning

confidence: 99%

Ductile bulk metallic glass by controlling structural heterogeneities

Scudino

Bian

Shahabi

et al. 2018

Sci Rep

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“…The deformation behavior of the initial, compressed, and HPT specimens was investigated. The yield strengths of the initial and compressed BMG were similar (Figure 11a) [85]. The tensile deformation behaviors of the HPT specimens were different as compared with that of initial BMG.…”

Section: Transformation Of the Properties Of Amorphous Alloys As A Rementioning

confidence: 87%

“…Herewith, it can lead to the formation of a high density of shear bands, where the spacing between the bands is about 50-100 nm [50]. In other works [24,41,[52][53][54][55][56][57]85], shear bands were not observed in the amorphous structure after HPT processing.…”

Section: Statementioning

confidence: 88%

“…The changes in the fracture surfaces can be interpreted as a successive increase of the material's local ductility due to HPT, which is connected with changes in the structure after HPT. Enhanced tensile ductility of the Zr65Al7.5Ni10Cu12.5Pd5 BMG after HPT was reported in [85]. The BMG was subjected to a compression stage and HPT processing.…”

Section: Transformation Of the Properties Of Amorphous Alloys As A Rementioning

confidence: 94%

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Influence of HPT Deformation on the Structure and Properties of Amorphous Alloys

Гундеров

Astanin

2020

Metals

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Recent studies showed that structural changes in amorphous alloys under high pressure torsion (HPT) are determined by their chemical composition and processing regimes. For example, HPT treatment of some amorphous alloys leads to their nanocrystallization; in other alloys, nanocrystallization was not observed, but structural transformations of the amorphous phase were revealed. HPT processing resulted in its modification by introducing interfaces due to the formation of shear bands. In this case, the alloys after HPT processing remained amorphous, but a cluster-type structure was formed. The origin of the observed changes in the structure and properties of amorphous alloys is associated with the chemical separation and evolution of free volume in the amorphous phase due to the formation of a high density of interfaces as a result of HPT processing. Amorphous metal alloys with a nanocluster structure and nanoscale inhomogeneities, representatives of which are nanoglasses, significantly differ in their physical and mechanical properties from conventional amorphous materials. The results presented in this review show that the severe plastic deformation (SPD) processing can be one of the efficient ways for producing a nanocluster structure and improving the properties of amorphous alloys.

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“…To date, there are several ways that have been developed to improve the room-temperature plasticity of BMGs, including intruding a secondary phase to develop a composite microstructure, surface coating, composition adjustment to induce intrinsic heterogeneity, severe plastic deformation such as shot peening and high pressure torsion [24][25][26][27]. Although introducing a secondary phase to make a composite structure seems to be most primal methods, it is reported that composite structure is one of the most efficient method and very easy to realize.…”

Section: How To Overcome the Problem?mentioning

confidence: 99%

Metallic Glass Matrix Composites

Guo¹

2018

Metallic Glasses - Properties and Processing

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In this chapter, we will firstly introduce the metallic glass and its deformation characteristics briefly. Then we will focus on the fabrication and mechanical properties of metallic glass matrix composites, including ex-situ particle/fiber reinforced, in-situ precipitated phase reinforced and etc. The alloy systems will cover from Zr-based, Ti-based to Mg-based and etc. We will also introduce the latest research on both new reinforcing phases and fabrication processes, including porous particles, shape memory phases, novel dealloying in metallic melt method, selective phase leaching method and so on. The microstructures, mechanical properties of each kind of composites, as well as the optimization methods, will be discussed in detail.

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Work-Hardening Induced Tensile Ductility of Bulk Metallic Glasses via High-Pressure Torsion

Cited by 84 publications

References 48 publications

Ductile bulk metallic glass by controlling structural heterogeneities

Ductile bulk metallic glass by controlling structural heterogeneities

Influence of HPT Deformation on the Structure and Properties of Amorphous Alloys

Metallic Glass Matrix Composites

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