Abstract
In this work, the current state of understanding of grain structure evolution during friction-stir welding is briefly reviewed. The broad aspects of this process and experimental techniques for its examination are critically addressed. The specific character of the microstructural evolutions in body-centered cubic, face-centered cubic and hexagonal close-packed metals are considered in details. In all cases, the grain structure evolution is shown to be a relatively complex process, which usually involves geometric effect of strain, continuous recrystallization and discontinuous recrystallization. Moreover, mechanical twinning, annealing twinning and grain convergence may also occur in particular cases. It is also demonstrated that activation of a specific microstructural mechanism is primarily governed by crystal structure and stacking fault energy but may also be influenced by welding temperature. Specifically, microstructure evolution in cubic metals with high stacking-fault energy is primarily governed by the continuous recrystallization whereas grain structure development in materials with low stacking-fault energy is mainly driven by the discontinuous recrystallization. In the case of transient stacking-fault energy, the materials may experience a transition from the continuous to the discontinuous mechanism. In hexagonal metals, microstructural changes are shown to be directly linked with crystallographic texture. Specifically, a formation of very sharp texture may promote the grain convergence.
Highlights
Friction-stir welding is an innovative technique which enables solid-state joining of materials [1,2,3]
Mechanical twinning, annealing twinning and grain convergence may occur in particular cases
The activation of particular microstructural me chanism is primarily governed by crystal structure as well as stacking fault energy of material but may be influenced by welding temperature
Summary
Friction-stir welding is an innovative technique which enables solid-state joining of materials [1,2,3]. The induced frictional heating and plas tic deformation rises the local temperature of the ma terial so it can be readily deformed Under this condi tion, the tool is traversed along the joint line. It should be emphasized that the authors of this work attempted to overview the current state-of-art in un derstanding of grain-structure development during friction-stir welding rather than identify individual con tributions to this issue. To this end, the following strat egy has been employed: (i) the key ideas and/or re sults were extracted from analysis of the body of work on the subject, (ii) they were appropriately categorized, and (iii) their brief review has been provided
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