Abstract
Multiple principal element alloys, also often referred to as compositionally complex alloys or high entropy alloys, present extreme challenges to characterize. They show a vast, multidimensional composition space that merits detailed investigation and optimization to identify compositions and to map the composition ranges where useful properties are maintained. Combinatorial thin film material libraries are a cost-effective and efficient way to create directly comparable, controlled composition variations. Characterizing them comes with its own challenges, including the need for high-speed, automated measurements of dozens to hundreds or more compositions to be screened. By selecting an appropriate thin film morphology through predictable control of critical deposition parameters, representative measured values can be obtained with less scatter, i.e., requiring fewer measurement repetitions for each particular composition. In the present study, equiatomic CoCrFeNi was grown by magnetron sputtering in different locations in the structure zone diagram applied to multinary element alloys, followed by microstructural and morphological characterizations. Increasing the energy input to the deposition process by increased temperature and adding high-power impulse magnetron sputtering (HiPIMS) plasma generators led to denser, more homogeneous morphologies with smoother surfaces until recrystallization and grain boundary grooving began. Growth at 300 °C, even without the extra particle energy input of HiPIMS generators, led to consistently repeatable nanoindentation load–displacement curves and the resulting hardness and Young’s modulus values.
Highlights
High entropy alloys (HEAs), referred to as multiple principal element alloys (MPEAs) or compositionally complex alloys (CCAs), are multinary materials where the constituent elements are in, or near, equiatomic concentrations
Thin films of the multiple principal element alloy CoCrFeNi were deposited by magnetron sputtering, varying the deposition temperature and particle energies
Characteristic microstructures of the structure zone diagram were obtained in spite of the multielement complexity
Summary
High entropy alloys (HEAs), referred to as multiple principal element alloys (MPEAs) or compositionally complex alloys (CCAs), are multinary materials where the constituent elements are in, or near, equiatomic concentrations. This is in contrast to traditionally developed alloys, which are based on one or two elements as the principal components with small amounts of additional elements that add, enhance, or adjust certain properties. A configurational entropy-based definition would lead to materials with a mixing entropy equal to or greater than 1.5R (where R is the gas constant, 8.314 J·K−1 mol−1 ) and a system where five or more elements would have a greater probability of forming solid solutions [5]. The investigation of MPEA systems extends beyond the search for single-phase solid solutions
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