Intrinsic correlation between fragility and bulk modulus in metallic glasses

Jiang, Minqiang; Dai, L.H.

doi:10.1103/physrevb.76.054204

Cited by 81 publications

(52 citation statements)

References 69 publications

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“…However, compared with the mean tensile stress, the shear-induced dilation in amorphous alloys is a secondary effect. 46,47 The volume dilation caused by deviatoric stress is significantly smaller than that caused by mean tensile stress, so we only consider mean tensile stress in this model.…”

Section: Decrease Of Activation Barriermentioning

confidence: 99%

How does spallation microdamage nucleate in bulk amorphous alloys under shock loading?

Huang

Zhong

Zhang

et al. 2011

Journal of Applied Physics

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Transmission electron microscopy of the amorphization of copper indium diselenide by in situ ion irradiation J. Appl. Phys. 111, 053510 (2012) Diffusion-controlled formation mechanism of dual-phase structure during Al induced crystallization of SiGe Appl. Phys. Lett. 100, 071908 (2012) Local structure of nitrogen in N-doped amorphous and crystalline GeTe Appl. Phys. Lett. 100, 061910 (2012) Facile creation of bio-inspired superhydrophobic Ce-based metallic glass surfaces Appl. Phys. Lett. 99, 261905 (2011) Unexpected short-and medium-range atomic structure of sputtered amorphous silicon upon thermal annealing J. Appl. Phys. 110, 096104 (2011) Additional information on J. Appl. Phys. Specially designed plate-impact experiments have been conducted on a Zr-based amorphous alloy using a single-stage light gas gun. To understand the microdamage nucleation process in the material, the samples are subjected to dynamic tensile loadings of identical amplitude ($ 3.18 GPa) but with different durations (83-201 ns). A cellular pattern with an equiaxed shape is observed on the spallation surface, which shows that spallation in the tested amorphous alloy is a typical ductile fracture and that microvoids have been nucleated during the process. Based on the observed fracture morphologies of the spallation surface and free-volume theory, we propose a microvoid nucleation model of bulk amorphous alloys. It is found that nucleation of microvoids at the early stage of spallation in amorphous alloys results from diffusion and coalescence of free volume, and that high mean tensile stress plays a dominant role in microvoid nucleation.

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Section: Decrease Of Activation Barriermentioning

confidence: 99%

How does spallation microdamage nucleate in bulk amorphous alloys under shock loading?

Huang

Zhong

Zhang

et al. 2011

Journal of Applied Physics

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“…Recently, it is found that the elastic moduli scaled with V m show better correlations with the thermal and mechanical properties for metallic glasses [17][18][20][21]. Thus, the characteristic volume could be an important parameter involved in the flow event in glass transition and glass.…”

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confidence: 99%

“…These BMGs cover many typical alloy systems, including Zr-, Cu-, Ca-, Mg-, Ni-, Fe-, and rare earth elements Fig. 1(b) confirms that the N involved in the cooperative flow event for various metallic glasses is almost the same.Based on above scaling laws and elastic model, we propose that it is the flow activation energy density (ρ E ), not the flow activation energy itself, correlates with the elastic moduli as:The extended elastic model means that the energy per volume needed in glass transition or in STZ in metallic glass is proportional to the elastic moduli.Previous elastic models [1] suggest that the atoms or atomic groups go through pure shearing displacement which is independent of K, and the ρ E depends only on G.Recent works [18,20] and the jamming model of granular systems [22] find that both shear and dilatation are involved in the flow during glass transition and deformation.Next, we further justify the flow activation energy density ρ E relates not to G or K but both G or K. That is, the flow event relate to both shearing transformation (corresponding to volume-preserving G) and dilatation (corresponding to volume-nonpreserving K). At T g , the ∆F/T g should be the same for all glasses that is independent of Poisson's ratio or other moduli [3].…”

mentioning

confidence: 99%

“…Among these models, the elastic models link the glass transition and elastic moduli of the glasses [1]. All the elastic models link the activation energy to the readily measurable instantaneous shear modulus G. In metallic glasses, the glass transition temperature (T g ) indeed shows clear correlation with the elastic moduli such as Young's modulus E and G [10][11][12][13][14][15][16][17][18].In this letter, based on the scaling laws between T g and elastic moduli in metallic glasses, we demonstrate that the V m scaled flow activation energy (∆F), that is, flow activation energy density, ρ Ε =∆F/V m , is determined by both G and K in a way of ρ Ε = (10G+K)/11. The physical origin of the extended elastic model is discussed.…”

mentioning

confidence: 99%

“…Recent works [18,20] and the jamming model of granular systems [22] find that both shear and dilatation are involved in the flow during glass transition and deformation.…”

mentioning

confidence: 99%

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Extended elastic model for flow in metallic glasses

Wang¹,

Wang²,

Bai³

2011

Journal of Non-Crystalline Solids

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We report that both shear and bulk moduli, not only shear modulus, are critical parameters involved in both homogeneous and inhomogeneous flows in metallic glass.The flow activation energy (∆F) of various glasses when scaled with average molar volume V m , which is defined as flow activation energy density ρ Ε =∆F/V m , can be expressed as: 11The extended elastic model is suggestive for understanding the glass transition and deformation in metallic glasses. The mysterious glass transition phenomenon, which connects the liquid and glassy state, has wide applications in daily life, industry, and organism preservation [1][2][3][4]. In the past decades, intensive efforts have been made to understand the glass transition [1,[5][6][7][8][9]. To understand the flow in supercooled liquid and glass, many models have been proposed. The well-known models are the free volume model, the Adam-Gibbs entropy model, the mode-coupling theory and elastic models [1][2][3][4][5][6]. A successful model of viscous liquids and glasses must explain why the activation energy has such strong temperature dependence and can correlate the activation energy to simple and readily measurable parameter. Among these models, the elastic models link the glass transition and elastic moduli of the glasses [1]. All the elastic models link the activation energy to the readily measurable instantaneous shear modulus G. In metallic glasses, the glass transition temperature (T g ) indeed shows clear correlation with the elastic moduli such as Young's modulus E and G [10][11][12][13][14][15][16][17][18].In this letter, based on the scaling laws between T g and elastic moduli in metallic glasses, we demonstrate that the V m scaled flow activation energy (∆F), that is, flow activation energy density, ρ Ε =∆F/V m , is determined by both G and K in a way of ρ Ε = (10G+K)/11. The physical origin of the extended elastic model is discussed.The temperature dependence of the viscosity of liquids approaching glass transition is [1]: ∆F∝G.Figure 1(a) shows experimental data of E and G versus T g for 46 different kinds of bulk metallic glasses (BMGs) (listed in Table I). These BMGs cover many typical alloy systems, including Zr-, Cu-, Ca-, Mg-, Ni-, Fe-, and rare earth elements Fig. 1(b) confirms that the N involved in the cooperative flow event for various metallic glasses is almost the same.Based on above scaling laws and elastic model, we propose that it is the flow activation energy density (ρ E ), not the flow activation energy itself, correlates with the elastic moduli as:The extended elastic model means that the energy per volume needed in glass transition or in STZ in metallic glass is proportional to the elastic moduli.Previous elastic models [1] suggest that the atoms or atomic groups go through pure shearing displacement which is independent of K, and the ρ E depends only on G.Recent works [18,20] and the jamming model of granular systems [22] find that both shear and dilatation are involved in the flow during glass transition and deformation.Next,...

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New Interpretation of Glass Formation in Isomeric Substances: Shifting from Melting‐Point to Melting‐Entropy

Ren

Zhang

et al. 2023

Advanced Science

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Revealing the critical thermodynamic parameters determining the glass formation of substances is of great significance for understanding the glass transition and guiding the composition design of glass‐forming materials. Nevertheless, the direct access to glass‐forming ability (GFA) by thermodynamics for various substances remains to be substantiated. The strategy to seek the fundamental properties of glass formation is explored several decades ago, as pioneered by Angell, arguing that the GFA in isomeric xylenes depends on the low lattice energy manifested by the low melting point. Here, an in‐depth study is advanced using two more isomeric systems. Surprisingly, the results do not constantly support the reported relationship between the melting point and glass formation among isomeric molecules. Instead, molecules with enhanced glass formability are featured by the properties of low melting entropy without exception. Comprehensive studies of isomeric molecules find that the low melting entropy is roughly accompanied by the low melting point, explaining the apparent link between melting point and glass formation. Progressively, the viscosity measurements of the isomers uncover a strong dependence of the melting viscosity on melting entropy. These results emphasize the significance of the melting entropy in governing the glass formability of substances.

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Intrinsic correlation between fragility and bulk modulus in metallic glasses

Cited by 81 publications

References 69 publications

How does spallation microdamage nucleate in bulk amorphous alloys under shock loading?

How does spallation microdamage nucleate in bulk amorphous alloys under shock loading?

Extended elastic model for flow in metallic glasses

New Interpretation of Glass Formation in Isomeric Substances: Shifting from Melting‐Point to Melting‐Entropy

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