Deformation of glass forming metallic liquids: Configurational changes and their relation to elastic softening

Harmon, John S.; Demetriou, Marios D.; Johnson, William L.; Tao, Min

doi:10.1063/1.2717017

Cited by 23 publications

(25 citation statements)

References 15 publications

(8 reference statements)

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“…As established previously [12], these liquids accommodate stress by undergoing an overshooting stress-strain response associated with a peak stress c and, ultimately, at a strain of 0:1 stabilize at a steady flow stress state. As argued previously [15], this uniaxial strain to steady state of 0:1, which roughly corresponds to an inelastic shear strain of 0.14, is observed to be universal for metallic glass-forming liquids and coincides with the crossing of megabasins whose average configurational spacing is estimated to be 4 c 4 0:036 0:14 [8]. This typical stress-strain response is also evident in the present sequential tests shown in Fig.…”

supporting

confidence: 63%

“…In the inset in Fig. 4, we plot the transient G data against the transient h data gathered here, superimposed on steady-state G vs h data gathered previously at 548 K for different strain rates [15]. As seen in the plot, the transient G data obey the same functional relationship with h as the steady-state data.…”

Section: Prl 99 135502 (2007) P H Y S I C a L R E V I E W L E T T E mentioning

confidence: 84%

“…Indeed, G has previously been shown to be uniquely and reversibly dependent on temperature [10,11,13] as well as strain rate [9,11]. More precisely, G was found to be a unique decreasing function of h independent of whether h is induced by thermal excitation or mechanical deformation [11,15]. This decreasing dependence of G on h reflects the decreasing curvature of the potential energy density function with increasing configurational energy and has been validated computationally [17].…”

Section: Prl 99 135502 (2007) P H Y S I C a L R E V I E W L E T T E mentioning

confidence: 89%

“…Ultrasonic measurements of the highfrequency shear modulus G plotted against the measured inelastic strain. Inset: Transient G vs h data gathered in the present study (ᮀ), together with steady-state G vs h data gathered previously ( ) [15]. (Note that the h datum in Ref.…”

Section: Prl 99 135502 (2007) P H Y S I C a L R E V I E W L E T T E mentioning

confidence: 99%

“…The isoconfigurational shear moduli at the experiment temperature were then estimated by extrapolating the room temperature measurements using a measured linear Debye-Grüneisen constant of 15 MPa=K [14]. The change in configurational potential energy at each transient stage was evaluated by measuring the change in recovered enthalpy h. Stored enthalpies were recovered by reheating the deformed specimens through the glass transition using differential scanning calorimetry, and changes referenced to the stored enthalpy of a specimen relaxed at 548 K with no imposed deformation were measured (see [15]). Finally, the ability of the material to undergo anelastic recovery at each transient stage was assessed by measuring the fraction of inelastic strain recovered upon subsequent annealing near T g (see [16]).…”

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confidence: 99%

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Anelastic to Plastic Transition in Metallic Glass-Forming Liquids

et al. 2007

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The configurational properties associated with the transition from anelasticity to plasticity in a transiently deforming metallic glass-forming liquid are studied. The data reveal that the underlying transition kinetics for flow can be separated into reversible and irreversible configurational hopping across the liquid energy landscape, identified with and relaxation processes, respectively. A critical stress characterizing the transition is recognized as an effective Eshelby ''backstress,'' revealing a link between the apparent anelasticity and the ''confinement stress'' of the elastic matrix surrounding the plastic core of a shear transformation zone. DOI: 10.1103/PhysRevLett.99.135502 PACS numbers: 61.43.Dq, 62.10.+s, 62.20.Dc, 62.40.+i Some of the earliest efforts to describe the mechanics of deformation and flow of metallic glasses and liquids were carried out by Argon [1]. Inspired by the deformation of soap bubble rafts [2], Argon proposed that these materials deform by plastic rearrangements of atomic regions involving tens of atoms, termed shear transformation zones (STZ's). Argon further recognized that these plastically rearranging regions were not free but confined within an elastic medium [3]. Using Eshelby's insightful analysis [4], he estimated the effect of elastic matrix confinement on the energy barrier separating the initial and transformed state of the STZ. He further argued that the elastic matrix confinement of an isolated transformed STZ would lead to reversible elastic energy storage in the STZ-matrix system, implying that transformed STZ's have a memory of their original untransformed state. Interestingly, Argon's concept was recently studied in a deforming metallic glass foam, where buckled membranes and their accommodating stress fields were observed to behave like elastically confined STZ's [5].As recognized by Johari and Goldstein [6], the underlying relaxation mechanisms of liquids and glasses are governed by two kinetic processes: a fast process, termed the process, viewed as a locally initiated and reversible process, and a slow process, termed the process, viewed as a large scale irreversible rearrangement of the material. From a potential energy landscape perspective, Debenedetti and Stillinger [7] have identified the transitions as stochastically activated hopping events across ''subbasins'' confined within the inherent ''megabasin'' (intrabasin hopping) and the transitions as irreversible hopping events extending across different landscape megabasins (interbasin hopping). A 1D section of a potential energy landscape illustrating this concept is presented schematically in Fig. 1. Johnson and Samwer [8] have recently shown that, by employing a sinusoidal function to describe the megabasin potential energy density, a scaling law for the yield strength of a frozen-in configuration arises in terms of the curvature of the potential energy density function (i.e., the isoconfigurational shear modulus), revealing a universal shear strain limit of c 0:036. More recently, Demetriou ...

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confidence: 63%

Section: Prl 99 135502 (2007) P H Y S I C a L R E V I E W L E T T E mentioning

confidence: 84%

Section: Prl 99 135502 (2007) P H Y S I C a L R E V I E W L E T T E mentioning

confidence: 89%

Section: Prl 99 135502 (2007) P H Y S I C a L R E V I E W L E T T E mentioning

confidence: 99%

mentioning

confidence: 99%

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Anelastic to Plastic Transition in Metallic Glass-Forming Liquids

et al. 2007

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Unraveling the threshold stress of structural rejuvenation of metallic glasses via thermo-mechanical creep

Ding

Jiang

Song

et al. 2022

Sci. China Phys. Mech. Astron.

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Observation of Shear Thickening during Compressive Flow of Mg54Y11Ag7Cu28 in the Supercooled Liquid Region

Ross

Mishra

Senkov³

et al. 2008

Metall Mater Trans A

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Uniaxial compression tests of Mg 54 Y 11 Ag 7 Cu 28 metallic glass were performed in the supercooled liquid region (SCLR) (468 K) at a strain rate range of 5 9 10 -4 to 2 9 10 -3 s -1 . In the course of testing, shear thickening behavior was observed, where the magnitude of the peak stress increases with increasing initial strain rate. The deformation behavior of the glassy metal is discussed with emphasis on the commonly reported stress overshoot, strain softening behavior, and the previously unreported shear thickening behavior observed.Metallic glasses have been the subject of intensive research following their discovery 50 years ago. The rapid crystallization kinetics of these early metallic glass ribbons prevented the study of the material above the glass transition. In the 1980s and 1990s, metallic glasses with slower crystallization kinetics were discovered; these materials are referred to as bulk metallic glasses (BMGs). [1] These new alloys allowed formation of metallic glasses with increased critical casting diameters, and they also permitted study of amorphous metal behavior in the supercooled liquid region (SCLR) above the glass transition temperature (T g ) but below the crystallization temperature. Of particular interest is the near Newtonian flow of BMGs in the SCLR. Strain rate sensitivity values (m values) between 0.8 and 1 are typically reported for low strain rates in the literature. [2] As a result of the Newtonian behavior, BMGs exhibit excellent superplastic properties. Tensile elongations above T g vary widely depending on testing and material parameters, but elongations in excess of 1000 pct have been observed in multiple alloy systems with some elongations exceeding 10,000 pct. [2][3][4] Furthermore, the strength of a BMG in the supercooled region is nearly an order of magnitude lower than the strength of the same material below T g . [5,6] An example of the low flow stresses in the SCLR is the superplastic blow forming performed on a Zr-based BMG. Parts with exceptional surface finish and feature replication were formed with gas pressures as low as 0.2 MPa. [6] Due to the exceptional formability and superplasticity exhibited by BMGs in the SCLR and their exceptional roomtemperature strengths, [7] BMGs show a great deal of promise in MEMS devices and other small scale, mechanically demanding applications. The most widely studied BMGs, such as Zr-based and Pd-based systems, have high densities and are very expensive. Lower density BMG systems, such as those that are Mg and Ca based, have comparatively low room-temperature fracture toughness. [8] The poor performance at room temperature has limited the amount of work being done on monolithic BMGs from these systems. The present study highlights material behavior discovered during compressive deformation in the SCLR of one Mg-based glass alloy. Uniaxial compression testing on cylindrical samples of Mg 54 Y 11 Ag 7 Cu 28 revealed that this alloy exhibits an m value greater than 1 when deformed in a narrow temperature range and at relatively l...

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Deformation of glass forming metallic liquids: Configurational changes and their relation to elastic softening

Cited by 23 publications

References 15 publications

Anelastic to Plastic Transition in Metallic Glass-Forming Liquids

Anelastic to Plastic Transition in Metallic Glass-Forming Liquids

Unraveling the threshold stress of structural rejuvenation of metallic glasses via thermo-mechanical creep

Observation of Shear Thickening during Compressive Flow of Mg54Y11Ag7Cu28 in the Supercooled Liquid Region

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