Abstract
Knowing the possible structures of individual clusters in nanostructured materials is an important first step in their design. With previous structure prediction data for BaO nanoclusters as a basis, data mining techniques were used to investigate candidate structures for magnesium oxide, calcium oxide and strontium oxide clusters. The lowest-energy structures and analysis of some of their structural properties are presented here. Clusters that are predicted to be ideal targets for synthesis, based on being both the only thermally accessible minimum for their size, and a size that is thermally accessible with respect to neighbouring sizes, include global minima for: sizes 
 
 
 
 n
 =
 9
 ,
 15
 ,
 16
 ,
 18
 
 
 
 and 24 for (MgO)
 
 
 
 
 n
 
 
 
 ; sizes 
 
 
 
 n
 =
 8
 ,
 9
 ,
 12
 ,
 16
 ,
 18
 
 
 
 and 24 for (CaO)
 
 
 
 
 n
 
 
 
 ; the greatest number of sizes of (SrO)
 
 
 
 
 n
 
 
 
 clusters (
 
 
 
 n
 =
 8
 ,
 9
 ,
 10
 ,
 12
 ,
 13
 ,
 15
 ,
 16
 ,
 18
 
 
 
 and 24); and for (BaO)
 
 
 
 
 n
 
 
 
 sizes of 
 
 
 
 n
 =
 8
 ,
 10
 
 
 
 and 16.
Highlights
Structure determination of materials plays an important role in materials design because the properties of materials are inherently linked to their atomic and electronic structure
Using the assumption that the potential energy surfaces (PES) of barium oxide clusters resemble those of clusters of the other alkaline earth oxides and that only the ranking of local minima (LM) changes instead of new low-energy structural motifs appearing, the aim is to reuse the LM structures gained from the evolutionary algorithm (EA) runs for BaO
Apart from changes in bond lengths and bond angles, we have initially assumed that the alkaline earth oxides can adopt the same set of LM configurations and that we have previously found the lowest energy LM for (BaO)n
Summary
Structure determination of materials plays an important role in materials design because the properties of materials are inherently linked to their atomic and electronic structure. Using the assumption that the potential energy surfaces (PES) of barium oxide clusters resemble those of clusters of the other alkaline earth oxides and that only the ranking of local minima (LM) changes instead of new low-energy structural motifs appearing, the aim is to reuse the LM structures gained from the EA runs for BaO. This should allow for a very efficient way of finding minima, and ideally the global minima (GM), for magnesium oxide, calcium oxide and strontium oxide clusters of the same sizes.
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