Abstract
How does a quasicrystal grow? Despite the decades of research that have been dedicated to this area of study, it remains one of the fundamental puzzles in the field of crystal growth. Although there has been no lack of theoretical studies on quasicrystal growth, there have been very few experimental investigations with which to test their various hypotheses. In particular, evidence of the in situ and three-dimensional (3D) growth of a quasicrystal from a parent liquid phase is lacking. To fill-in-the-gaps in our understanding of the solidification and melting pathways of quasicrystals, we performed synchrotron-based X-ray imaging experiments on a decagonal phase with composition of Al-15at%Ni-15at%Co. High-flux X-ray tomography enabled us to observe both growth and melting morphologies of the 3D quasicrystal at temperature. We determined that there is no time-reversal symmetry upon growth and melting of the decagonal quasicrystal. While quasicrystal growth is predominantly dominated by the attachment kinetics of atomic clusters in the liquid phase, melting is instead barrier-less and limited by buoyancy-driven convection. These experimental results provide the much-needed benchmark data that can be used to validate simulations of phase transformations involving this unique phase of matter.
Highlights
Since the discovery of quasicrystals (QCs) by Shechtman in 19841,2, the growth mechanism of QCs has stimulated the curiosity of researchers worldwide due to their unique structure[3,4,5,6,7,8,9,10,11,12]
The QC is anchored to this oxide skin on both sides and the QC does not sediment to the bottom of the melt
The growth and melting processes do not have time-reversal symmetry and different physical principles must be invoked in order to explain these different behaviors
Summary
Since the discovery of quasicrystals (QCs) by Shechtman in 19841,2, the growth mechanism of QCs has stimulated the curiosity of researchers worldwide due to their unique structure[3,4,5,6,7,8,9,10,11,12]. The structures of the three-dimensional QCs are quasiperiodic in all three dimensions (e.g., icosahedral QCs) That is, they do not have translational periodicity in any direction. There are still unanswered questions in terms of the underlying kinetics, surface properties, and defects To answer these questions, refs[5,6,7] have analyzed the growth of icosahedral QCs via in situ X-ray radiography (i.e., projection videomicroscopy). Refs[5,6,7] have analyzed the growth of icosahedral QCs via in situ X-ray radiography (i.e., projection videomicroscopy) They studied the interfacial velocity of the facets and edges in the icosahedral QC during directional solidification. In situ and 3D experimental studies on the growth and melting of QCs from a parent liquid phase have not been demonstrated yet, to the best of our knowledge
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