We have found that GB phase transitions are a common phenomena 4,16-21. The packing density of GB atoms and the bonding interactions up to the second nearest neighbors determine the GB phase 21. Upon segregation, differences in structural units can occur: for Zr the structure motifs of a Cu GB get more distorted22, with decoration starting first at disconnections. In contrast, Ag modifies the Cu GB structure units and fills certain places first 23,24. Electrical resistivity of grain boundaries depends strongly on the excess volume as found for Cu tilt grain boundaries. Interestingly, dilute segregation (<0.4 at%) leads to a measurable change of GB resistivity as for the case of Cu containing trace levels of Fe, where an increase in GB resistivity by 1000% was found 25.
For the formation of disconnections, the structural units play an important role as they can exclude some Burgers vectors and step heights in case they don’t match with the repeat units of the structural GB motifs as found by atomistic simulations 19. The gained fundamental knowledge on GB atomistics is not only of academic interest, but has important consequences for grain growth, shear coupled GB motion and applications of metallization and conduction lines in semiconductor devices.
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