Universal mechanical response of metallic glasses during strain-rate-dependent uniaxial compression
Abstract
Experimental data on the compressive strength σ max versus strain rate eng for metallic glasses undergoing uniaxial compression shows significantly different behavior for different alloys. For some metallic glasses, σ max decreases with increasing eng, for others, σ max increases with increasing eng, and for others σ max versus eng is nonmonotonic. Using numerical simulations of metallic glasses undergoing uniaxial compression at nonzero strain rate and temperature, we show that they obey a universal relation for the compressive strength versus temperature, which determines their mechanical response. At low eng, increasing strain rate leads to increases in temperature and decreases in σ* max, whereas at high eng, increasing strain rate leads to decreases in temperature and increases in σ* max. This non-monotonic behavior of σ* max versus temperature causes the nonmonotonic behavior of σ* max versus eng. Variations in the internal dissipation change the characteristic strain rate at which the nonmonotonic behavior occurs. These results are general for a wide range of metallic glasses with different atomic interactions, damping coefficients, and chemical compositions.
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