The uniqueness of the thermodynamic non-equilibrium sputtering processes used for the synthesis of the multi-principal element alloys and metallic films in this project allowed for the fabrication of compositions and microstructures, which are not accessible by thermal treatment, commonly used to control phase composition of bulk alloys. This allowed to study phenomena in the materials science, which are expected to enhance properties of alloys and metals, but could be studied in bulk materials only in specific cases of highly deformed materials, by e.g. high pressure torsion technique or additive manufacturing processes. Although the first approach is capable to produce nanostructured alloys, there are usually very defective, exhibiting high residual stresses. The latter approach, on the other hand, still does not produce materials with grains in the nanometre range.
Designing the multi-principal element alloys with complex microstructures, varying in the grain size, exhibiting twins with specific distributions and separation distances, with decorated grain boundaries and with varying amount and composition of precipitates formed during the controlled decomposition of the primary phase, goes beyond the state-of-the-art material design.
The combination of the conventional methods with multimodal complementary advanced characterization methods and new characterization approaches, including the unique 4D STEM technique utilizing pixel array detectors and dual-beam deep UV laser pulse APT with a new counter electrode concept, makes this project exceptional, significantly contributing to the understanding of fundamental material science phenomena.
By deriving novel design concepts of interface-rich hierarchical structures, the project has ambitions to develop novel durable structurally and compositionally complex metallic materials and alloys, which may solve some non-trivial material science questions (such as strength-ductility trade-off) and contribute to the replacement of some traditional materials with insufficient properties.