Abstract
Steady state deformation has been characterized based on the experimental results for dilute single-phase aluminium alloys. It was found that although characteristic properties such as flow stress and grain size remained constant with time, a continuous loss of grain boundaries occurred as an essential feature at steady state. A physical model, which takes into account the activity of grain boundary dislocations, was developed to describe the kinetics of steady state deformation. According to this model, the steady state as a function of strain rate and temperature defines the limit of the conventional grain size and strength relationship, i.e., the Hall-Petch relation holds when the grain size is larger than that at the steady state, and an inverse Hall-Petch relation takes over if grain size is smaller than the steady state value. The transition between the two relationships relating grain size and strength is a phenomenon that depends on deformation conditions, rather than an intrinsic property as generally perceived. A general scale law of deformation is established accordingly.
Highlights
Related content- Modeling the effect of deformation on strength of a Fe-23Mn-0.3C-1.5Al TWIP steel P Kusakin, A Belyakov, R Kaibyshev et al
From early studies on face-centred cubic crystalline metals and alloys it is known that stress– strain curves exhibit well-defined stages and microstructure dependencies [1,2,3]
Irrespective of whether dynamic recrystallization occurs, the strain rate and temperature dependence of the steadystate stress is often described by an empirical equation [7, 8]:
Summary
- Modeling the effect of deformation on strength of a Fe-23Mn-0.3C-1.5Al TWIP steel P Kusakin, A Belyakov, R Kaibyshev et al. - Superstrength of nanostructured alloys produced by SPD processing R Z Valiev, N A Enikeev and X Sauvage. - High strength state of UFG steel produced by severe plastic deformation N A Enikeev, X Sauvage, M M Abramova et al
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