Temperature dependent dynamics transition of intermittent plastic flow in a metallic glass. I. Experimental investigations

Liu, Zy Y.; Wang, G.; Chan, Kang Cheung; Ren, Jingli; Huang, YJ; Bian, Xilei; Xu, Xiaohang; Zhang, Ds S.; Gao, Yun; Zhai, Qijie

doi:10.1063/1.4815943

Cited by 18 publications

(15 citation statements)

References 33 publications

(43 reference statements)

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“…Therefore, it is required to uncover the correlation between the strength and the fracture behaviors of BMGs under different temperatures, and loading rates. Abundant researches have been carried out to explore the influence of cryogenic temperature on the strength and the plastic behavior (serrated flow) of BMGs in the past several years5910111213. The quasi-static deformation tests as well as the dynamic deformation tests of many BMGs also were performed, which suggested a negative-sensitivity of strength to strain rate681415161718192021.…”

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confidence: 99%

Rate dependent of strength in metallic glasses at different temperatures

Wang

Bian

et al. 2016

Sci Rep

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The correlation between the strength at the macroscale and the elastic deformation as well as shear cracking behavior at the microscale of bulk metallic glasses (BMGs) is investigated. The temperatures of 298 K and 77 K as well as the strain rate ranging from 10−6 s−1 to 10−2 s−1 are applied to the BMGs, in which the mechanical responses of the BMGs are profiled through the compression tests. The yield strength is associated with the activation of the elementary deformation unit, which is insensitive to the strain rate. The maximum compressive strength is linked to the crack propagation during shear fracture process, which is influenced by the strain rate. The cryogenic temperature of 77 K significantly improves the yield strength and the maximum compressive strength of the BMGs.

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confidence: 99%

Rate dependent of strength in metallic glasses at different temperatures

Wang

Bian

et al. 2016

Sci Rep

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“…Once the shear band is formed, an elastic-strain field can appear in the front of the shear-band tip, which is analogy to the elastic-strain field in the front of the crack tip. The size of the elastic-strain field is several times larger than the inter-spacing between two neighboring shear bands (Liu et al, 2013a), which causes the overlap of two elastic-strain fields initiated from neighboring shear bands. The overlap of the elastic-strain field can result in a hierarchy of length scales (Bharathi et al, 2001), leading to a self-organized critical behavior that is manifested as a scaling behavior of the shear-avalanche statistics.…”

Section: Discussionmentioning

confidence: 99%

“…Acoustic-emission experiments have clearly shown that the dynamic behavior of the shear-avalanche can be associated with the elementary mechanisms of energy dissipation (Klaumünzer et al, 2011a;Kumar and Ananthakrishna, 2011;Koslowski et al, 2004;Dimiduk et al, 2006). This energy relaxation duration is significantly affected by the environmental temperature (Klaumünzer et al, 2011b), strain rate (Liu et al, 2013a;Ren et al, 2011), and outside geometric confinement (Wang et al, 2009), which can modify the dynamic behavior of metallic glasses. From this point, a crucial question is raised: how does the dynamics of the intermittent deformation change, when this jerky flow is disturbed, and how does then the plastic deformability of metallic glasses change?…”

Section: Introductionmentioning

confidence: 99%

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Shear avalanches in plastic deformation of a metallic glass composite

Tong

Wang

et al. 2016

International Journal of Plasticity

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Changes in intermittent shear avalanches during plastic deformation of a Cu 50 Zr 45 Ti 5 (atomic percent) alloy in response to variant structures including fully glassy phase and/or nanocrystal/glass binary phase are investigated. Second crystalline phases are introduced into the glassy-phase matrix of a Cu 50 Zr 45 Ti 5 metallic glass to interfere with the shear-avalanche process, which can release the shear-strain concentration, and then tune the critically-dynamic behavior of the shear avalanche. By combining microstructural observations of the nanocrystals with the statistical analysis of the corresponding deformation behavior, we determine the statistic distribution of shear-avalanche sizes during plastic deformation, and established its dependence on the geometric distribution of nanocrystals. The scaling behavior of the distribution of shear-avalanche sizes follows a power-law relation accompanied by an exponentially-decaying scaling function in the pure metallic glass, and the metallic glass containing the small nanocrystals, which can be described by the mean-field theory. The large shear-avalanche events are dominated by structural tuning-parameters, i.e., the resistance of shear banding, and the size and volume fraction of the second crystalline phase in metallic glasses.

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“…According to Figure 3, the K Q value decreases approximately 43% when the temperature is decreased from 298 to 123 K. In the meantime, the decrease in the temperature causes the yield strength of the MG to increase roughly 20% [36]. Therefore, the R value at 298 K is almost 4.4 times larger than the value at 123 K. The increased γ value and the reduced r H value with the decreasing temperature suggests that the softening behavior is weakened, which is the main reason causing the difference in the fracture surfaces generated at different temperatures.…”

Section: Discussionmentioning

confidence: 99%

Reduced Fracture Toughness of Metallic Glass at Cryogenic Temperature

Zhou

Liu

Han

et al. 2017

Metals

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Abstract:The effects of cryogenic temperature on the toughness of a Zr-based metallic glass are investigated. Based on three-dimensional fracture morphologies at different temperatures, the crack formation and propagation are analyzed. Through the calculation of the shear transformation zone volume, the shear modulus and bulk modulus of the metallic glass at different temperatures and the crack formation mechanism associated with the temperature is discussed. Once the crack commences propagation, the hyperelasticity model is used to elucidate the fractographic evolution of crack propagation.

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Temperature dependent dynamics transition of intermittent plastic flow in a metallic glass. I. Experimental investigations

Cited by 18 publications

References 33 publications

Rate dependent of strength in metallic glasses at different temperatures

Rate dependent of strength in metallic glasses at different temperatures

Shear avalanches in plastic deformation of a metallic glass composite

Reduced Fracture Toughness of Metallic Glass at Cryogenic Temperature

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