A quantitative connection between shear band mediated plasticity and fracture initiation toughness of metallic glasses

While it is well recognized, albeit qualitatively, that shear band mediated plasticity ahead of crack or notch tips is the raison d'être for the high fracture toughness of 'ductile' bulk metallic glasses (BMGs), quantitative connection between those two material properties is yet to b...

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Bibliographic Details
Published in:Acta materialia 2018-05, Vol.150, p.69-77
Main Authors: Narayan, R.L., Raut, Devaraj, Ramamurty, U.
Format: Article
Language:English
Subjects:
Bulk metallic glass
Fracture toughness
Mechanical behavior
Plastic deformation
Shear bands
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Summary:While it is well recognized, albeit qualitatively, that shear band mediated plasticity ahead of crack or notch tips is the raison d'être for the high fracture toughness of 'ductile' bulk metallic glasses (BMGs), quantitative connection between those two material properties is yet to be established. In an attempt to study this, we examine if mode I fracture initiation toughness, KIc, of a number of BMGs can be related to the shear band number, Ni, which is a discretized measure of plasticity in MGs, around spherical indentation impressions that are made to a fracture mechanism based predetermined indentation strain. Results show that KIc scales with (Ni)3/2. Then, the relation between the shear band density in the notch tip plastic zone, Nn, and KIc is examined, which shows that a power law: KIc∝(Nn)1/2, captures the data reported in literature for a number of BMGs. This result confirms that it is indeed the notch tip plasticity that determines KIc of BMGs. The power law exponent of 0.5 is rationalized by recourse to elasto-plastic fracture mechanics. Possible connections between Ni and Nn, ways of enhancing the latter so as to increase KIc, and the central role played by the relative density of MGs in determining both elastic, plastic, and fracture responses are discussed. [Display omitted]
ISSN:1359-6454
1873-2453
DOI:10.1016/j.actamat.2018.03.011